Life Sciences and Agriculture

Journal of Plant Protection Research

Description

4 issues per year.

The online version of Journal of Plant Protection Research (JPPR) is the original one.

Rejection rate – over 70%.

Journal of Plant Protection Research is an international peer-reviewed journal that publishes original papers, rapid communications, reviews, covering all areas of plant protection. Subjects include phytopathological virology, bacteriology, mycology and applied nematology and entomology as well as topics on protecting crop plants and stocks of crop products against diseases, viruses, weeds etc.

The Journal is published by Institute of Plant Protection – National Research Institute and Committee on Agronomic Sciences of the Polish Academy of Sciences. By 1997 under the title Prace Naukowe Instytutu Ochrony Roślin and Annals of Agricultural Sciences - Series E - Plant Protection).

Journal scope

JPPR publishes original research papers, rapid communications, critical reviews, and book reviews covering all areas of modern plant protection. Subjects include phytopathological virology, bacteriology, mycology and applied nematology and entomology as well as topics on protecting crop plants and stocks of crop products against diseases, viruses, weeds etc. We publish papers which use an interdisciplinary approach showing how different control strategies can be integrated into pest management programmes, which cover high and low input agricultural systems worldwide, within the framework of ecologically sound and economically responsible land cultivation.

Relevant topics include: advanced methods of diagnostic, and computer-assisted diagnostic plant research and new findings, biological methods of plant protection, selective chemical methods of plant protection, the effects of plant-protecting agents and their toxicology, methods to induce and utilize crop resistance, application techniques, and economic aspects of plant protection.

Journal of Plant Protection Research is also available on:

http://www.plantprotection.pl/

The Journal does not have article processing charges (APCs) nor article submission charges.

Journal Metrics:

IMPACT FACTOR 2022: 1.1

CiteScore metrics from Scopus 2022: 2.3

SCImago Journal Rank (SJR) 2022: 0.289

Source Normalized Impact per Paper (SNIP) 2022: 0.570

ISSN

ISSN 1427-4345, eISSN 1899-007X

Publishers

Committee of Plant Protection PAS, Institute of Plant Protection – National Research Institute

Editor-in-Chief

Prof. Natasza Borodynko-Filas (Virology and Bacteriology)

0000-0002-4217-6421
Plant Disease Clinic and Bank of Pathogens
Institute of Plant Protection - National Research Institute
Władysława Węgorka 20, 60-318 Poznań, Poland
e-mail: n.borodynko@iorpib.poznan.pl

Deputy Editor-in-Chief

Assoc. prof. Piotr Kaczyński (Pesticide Residue)

0000-0002-3511-752X
Institute of Plant Protection - National Research Institute, Poznań, Poland

Scientific Board

Prof. Grzegorz Bartoszewski (Molecular Biology)

0000-0002-6197-770X
Warsaw University of Life Sciences, Warsaw, Poland

Dr. Ulrike Damm (Mycology)
Senckenberg Museum of Natural History, Görlitz, Germany

Prof. Santiago F. Elena (Plant Virology)

0000-0001-8249-5593
Instituto de Biología Integrativa de Sistemas, valencia, Spain

Prof. Bernd Freier
Institut für Integrierten Pflanzenschutz, Kleinmachnow, Germany

Prof. Beata Hasiów-Jaroszewska (Virology and Bacteriology)

0000-0002-8267-023X
Institute of Plant Protection - National Research Institute, Poznań, Poland

Prof. Asghar Heydari (Plant Pathology)
Iranian Research Institute of Plant Protection, Teheran, Iran

Dr. Andrew Hewitt (Agricultural Engineering)

0000-0001-9210-7013
The University of Queensland, Brisbane, Australia

Prof. Karl Hurle (Weed Science)
University of Hohenheim, Stuttgart, Germany

Dr. Thomas Jung (Plant Pathology)

0000-0003-2034-0718
Mendel University in Brno, Brno, Czech Republic

Prof. Mohamed F.R. Khan (Plant Pathology)
North Dakota State University and University of Minnesota, USA

Dr. Opender Koul (Biological Control, Entomology)
Insect Biopesticide Research Centre, Jalandhar, India

Assoc. prof. László Kredics (Biological Control)

0000-0003-2034-0718
University of Szeged, Szeged, Hungary

Prof. Per Kudsk (Weed Science)

0000-0003-2431-3610
Aarhus University, Flakkebjerg, Slagelse, Denmark

Prof. Thomas Kühne
Julius Kühn-Institut, Federal Research Centre for Cultivated Plants, Quedlinburg, Germany

Prof. Maria López (Bacteriology)
The Valencian Institute of Agrarian Research (IVIA), Moncada, Spain

Prof. Enrique Monte Vázguez
Universidad de Salamanca, Salamanca, Spain

Assoc. prof. Aleksandra Obrępalska-Stęplowska (Molecular Biology)

0000-0002-0314-8110
Institute of Plant Protection - National Research Institute, Poznań, Poland

Dr. Karel Petrzik (Plant Virology)

0000-0001-9668-1223
Institute of Plant Molecular Biology, Ceske Budejovice, Czech Republic

Assoc. prof. Jacek Piszczek (Plant Pathology)

0000-0003-1654-1955
Institute of Plant Protection - National Research Institute, Poznań, Poland

Prof. Henryk Pospieszny

0000-0001-6769-8931
Institute of Plant Protection - National Research Institute, Poznań, Poland

Prof. Baruch Rubin (Weed Science)

0000-0001-5748-3099
Hebrew University of Jerusalem, Jerusalem, Israel

Assoc. prof. Zuzanna Sawinska (Agronomy)

0000-0002-7030-3221
University of Life Sciences, Poznań, Poland

Dr. Marcela Ines Schneider (Biological Control)

0000-0001-5666-7742
Centro de Estudios Parasitologicos y de Vectores (CEPAVE), La Plata, Argentina

Prof. Piotr Sobiczewski (Plant Pathology)

0000-0001-9925-3611
Research Institute of Horticulture, Skierniewice, Poland

Prof. Piotr Szulc (Agronomy)

0000-0002-9670-3231
University of Life Sciences, Poznań, Poland

Dr. James E. Throne (Entomology)
United States Department of Agriculture, Agricultural Research Service, Parlier, USA

Prof. Marek Tomalak (Biological Control)

0000-0002-4132-4445
Institute of Plant Protection - National Research Institute, Poznań, Poland

Prof. Zenon Woźnica (Weed Science)
University of Life Sciences, Poznań, Poland

Associate Editors

Dr. Iwona Adamska (Plant Pathology)

0000-0002-9185-3249
West Pomeranian University of Technology, Szczecin, Poland

Assoc. prof. Arkadiusz Artyszak (Agronomy)

0000-0002-0272-1536
Warsaw University of Life Sciences, Warsaw, Poland

Dr. Zbigniew Czaczyk (Agricultural Engineering)
Poznan Univeristy of Life Sciences, Poznań, Poland

Dr. Kallol Das (Plant Pathology)

0000-0003-0906-3983
College of Agriculture and Life Sciences, Kyungpook National University, Daegu, South Korea

Assoc. prof. Renata Dobosz (Zoology)

0000-0002-4660-7743
Institute of Plant Protection - National Research Institute, Poznań, Poland

Dr. Anna Filipiak (Biological Control)

0000-0001-7307-5116
Institute of Plant Protection - National Research Institute, Poznań, Poland

Assoc. prof. Lidia Irzykowska (Plant Pathology, Mycology)

0000-0001-5731-1668
Poznan Univeristy of Life Sciences, Poznań, Poland

Dr. Magdalena Jakubowska (Entomology)

0000-0001-9108-8965
Institute of Plant Protection - National Research Institute, Poznań, Poland

Dr. Magdalena Karbowska-Dzięgielewska (Entomology)

0000-0003-2866-2375
West Pomeranian University of Technology, Szczecin, Poland

Dr. Przemysław Kardasz (Weed Science)

0000-0001-6259-2409
Institute of Plant Protection - National Research Institute, Poznań, Poland

Dr. Chetan Keswani (Biological Control)

0000-0002-2786-121X
Banaras Hindu University, Varanasi, India

Dr. Tomasz Klejdysz (Entomology)

0000-0002-9660-9771
Institute of Plant Protection - National Research Institute, Poznań, Poland

Dr. Franciszek Kornobis (Zoology)
Institute of Plant Protection - National Research Institute, Poznań, Poland

Dr. Krzysztof Krawczyk (Virology and Bacteriology)

0000-0002-6279-4921
Institute of Plant Protection - National Research Institute, Poznań, Poland

Dr. Wojciech Kubasik (Entomology)

0000-0001-9680-8220
Institute of Plant Protection - National Research Institute, Poznań, Poland

Dr. Rafał Kukawka (Chemistry)

0000-0002-1073-496X
Poznan Science and Technology Park, Poznań, Poland

Dr. Karlos Lisboa (Biotechnology)
Institute of Chemistry and Biotechnology, Federal University of Alagoas, Alagoas, Brazil

Dr. Vahid Mahdavi (Entomology)
Ardabil Agricultural and Natural Resources Research and Education Center, AREEO, Ardabil, Iran

Assoc. prof. Kinga Matysiak (Weed Science)

0000-0001-8082-9342
Institute of Plant Protection - National Research Institute, Poznań, Poland

Dr. Julia Minicka (Virology and Bacteriology)

0000-0002-7773-9079
Institute of Plant Protection - National Research Institute, Poznań, Poland

Assoc. prof. Ewa Moliszewska (Mycology)

0000-0003-4919-5139
Universitas Opoliensis, Poland

Prof. Joanna Puławska (Bacteriology)

0000-0001-5327-1056
The National Institute of Horticultural Research, Poland

Dr. Tomasz Sekutowski (Weed Science)

0000-0002-5176-337X
Institute of Soil Science and Plant Cultivation - State Research Institute, Puławy, Poland

Assoc. prof. Łukasz Sobiech (Weed Science)

0000-0002-2584-9911
University of Life Sciences, Poznań, Poland

Dr. Sebastian Stenglein (Mycology)
National University of the Centre of the Buenos Aires Province, Argentina

Dr. Andrea V. Toledo (Biological Control, Entomology)

0000-0001-6930-0077
Centro de Investigaciones de Fitopatología, Facultad de Ciencias Agrarias y Forestales, Universidad Nacional de La Plata, Buenos Aires, Argentina

Assoc. prof. Anna Tratwal (Integrated Crop Management)

0000-0001-9611-8799
Institute of Plant Protection - National Research Institute, Poznań, Poland

Dr. Yongzhi Wang (Virology and Bacteriology)

0000-0002-6586-6652
Jilin Academy of Agricultral Sciences, Changchun, Jilin Province, China

Dr. Przemysław Wieczorek (Biotechnology)

0000-0002-3306-9763
Institute of Plant Protection - National Research Institute, Poznań, Poland

Dr. Huan Zhang (Plant Pathology)

0000-0002-2953-6162
Texas A&M University, Texas, USA

Managing Editors

Małgorzata Maćkowiak
e-mail: m.mackowiak@iorpib.poznan.pl

Monika Kardasz
e-mail: m.kardasz@iorpib.poznan.pl

Proofreader in English
Delia Gosik
Halina Staniszewska-Gorączniak

Statistical Editor
Dr. Jan Bocianowski, MS Agata Pruciak

Technical Editor
Tomasz Adamski

Journal of Plant Protection Research

Institute of Plant Protection
National Research Institute
Władysława Węgorka 20
60–318 Poznań, Poland

tel.: +48 61 864 90 30
e-mail: office@plantprotection.pl

Managing Editors

Malgorzata Mackowiak
m.mackowiak@iorpib.poznan.pl

Monika Kardasz
m.kardasz@iorpib.poznan.pl

Journal of Plant Protection Research is an open access journal with all content available with no charge in full text version.

The journal content is available under the licencse CC BY-NC-ND 4.0. https://creativecommons.org/licenses/by-nc-nd/4.0/

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Content

Journal of Plant Protection Research | 2024 | vol. 64 | No 2

1 Enhancing toxicity of pyrethroids by oxidase and esterase inhibitors in Spodoptera littoralis (Boisd.) larvae

Seham Mansour Ismail

Journal of Plant Protection Research | 2024 | vol. 64 | No 2 | 87-91 | DOI: 10.24425/jppr.2024.149162

Keywords: pyrethroid resistance resistance management synergism

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Abstract

Although pyrethroids are increasingly being used to control a number of agricultural insect pests, especially the cotton leafworm, Spodoptera littoralis (Boisd.), pyrethroid resistance is a major obstacle limiting effective control. With the aim of maintaining the effectiveness of pyrethroids in managing pests, a study was undertaken to evaluated the effectiveness of oxidase and esterase inhibitors for synergizing pyrethroids in S. littoralis larvae. Compared with the insecticide-susceptible strain (L-SS) of S. littoralis, the resistance ratio (RR) in the field population (F-RS) was 271.43–fold to cypermethrin. The use of profenofos as an esterase inhibitor significantly increased larval susceptibility to cypermethrin in the F-RS strain, with a synergy ratio (SR) of up to 192.57–fold. Significant inhibition of esterase by profenofos in the F-RS strain was found in vivo. Also, piperonyl butoxide (PB) as an oxidase inhibitor had slight effect of cypermethrin toxicity, so its addition is not a solution for pyrethroid resistance. Thus, modifying the toxicity of cypermethrin by mixing it with organophosphorus compounds (OPs) increased its toxicity and decreased the population of S. littoralis, which is a successful strategy for managing pyrethroid resistance.

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Authors and Affiliations

Seham Mansour Ismail

Insect Population Toxicology Department, Central Agricultural Pesticides Laboratory, Agriculture Research Center, Giza, Egypt

2 Phytochemical characterization by HS-SPME-GC-MS and exploration of the antifungal, insecticidal and repellent activity of Ptychotis verticillata essential oil

Mohamed Taibi , Amine Elbouzidi , Aimad Allali , El Hassania Loukili , Mohamed Addi , Samiah Hamad Al-Mijalli , Reda Bellaouchi , Abdeslam Asehraou , Ammmar AL-Farga , Hanae Naceiri Mrabti , Mohammed Bourhia , Bouchra El Guerrouj , Khalid Chaabane

Journal of Plant Protection Research | 2024 | vol. 64 | No 2 | 92-105 | DOI: 10.24425/jppr.2024.149161

Keywords: antifungal activity essential oil HSPME-GC-MS insecticidal activity Ptychotis verticillata

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Abstract

The objective of this investigation was to assess the chemical makeup of essential oil derived from Ptychotis verticillata (PVEO), and to examine its antifungal, insecticidal, and repellent properties. PVEO was extracted through hydrodistillation, and its volatile constituents were analyzed using Headspace Solid-Phase Microextraction Gas Chromatography-Mass Spectrometry. Qualitative and quantitative evaluation of antifungal activity was carried out using the agar diffusion method and the minimum inhibitory concentration (MIC) test against Candida glabrata, Saccharomyces cerevisiae, Aspergillus niger and Penicillium digitatum. We evaluated the repellent potential, as well as the contact and inhalation toxicity of PVEO against Callosobruchus maculatus. The results of the study indicated that the essential oil of P. verticillata was composed mainly of γ-Terpinen (25.86%), β-Cymene (18.70%) O-Cymen-5-ol (16.78) and α-Pinene (12.13%). PVEO showed potent antifungal activity against all strains tested. The results of insecticidal activity of this essential oil were promising in adult C. maculatus. At a dose of 20 ml · dm^–3 of air, EO caused maximum mortality with an LC₅₀ value of 5.64 ml · dm^–3 for the inhalation test and 3.4 ml · dm^–3 for the contact test. In addition, a significant decrease in the number of eggs laid and adult emergence was observed as EO doses increased, reaching a reduction of around 95% at a dose of 20 ml · dm^–3 of air. In terms of repellent activity, PVEO also showed encouraging results. It demonstrated an average repellent activity of around 92 ± 10.95%. Furthermore, molecular docking simulations corroborated the in vitro results and demonstrated that specific p-Menthen-3-one compounds formed more robust hydrogen bonding interactions with the target receptors. These experiments underscore PVEO’s effectiveness as a fungicide against the tested fungal strains, demonstrating its role as a bio-insecticide against C. maculatus adults, and its potential as an appealing repellent. This suggests that PVEO could serve as a valuable alternative within integrated pest management strategies.

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Authors and Affiliations

Mohamed Taibi

Amine Elbouzidi

Aimad Allali

El Hassania Loukili

Mohamed Addi

Samiah Hamad Al-Mijalli

Reda Bellaouchi

Abdeslam Asehraou

Ammmar AL-Farga

Hanae Naceiri Mrabti

Mohammed Bourhia

Bouchra El Guerrouj

Khalid Chaabane

Laboratory for Agricultural Productions Improvement, Biotechnology and Environment (LAPABE), Faculty of Sciences, University of Mohammed Premier, Oujda, Morocco; Center of Oriental Water and Environmental Sciences and Technologies (COSTEE), Mohammed First University, Oujda, Morocco
Laboratory for Agricultural Productions Improvement, Biotechnology and Environment (LAPABE), Faculty of Sciences, University of Mohammed Premier, Oujda, Morocco; Euro-Mediterranean University of Fes (UEMF), Fes, Morocco
Laboratory of Plant, Animal, and Agro-Industry Productions, Faculty of Sciences, University of Ibn Tofail, Kenitra, Morocco; High Institute of Nursing Professions and Health Techniques annex Taza, Fez, Morocco
Center of Oriental Water and Environmental Sciences and Technologies (COSTEE), Mohammed First University, Oujda, Morocco; Euro-Mediterranean University of Fes (UEMF), Fes, Morocco
Laboratory for Agricultural Productions Improvement, Biotechnology and Environment (LAPABE), Faculty of Sciences, University of Mohammed Premier, Oujda, Morocco
Department of Biology, College of Sciences, Princess Nourah Bint Abdulrahman University, Riyadh, Saudi Arabia
Laboratory of Bioresources, Biotechnology, Ethnopharmacology and Health, Faculty of Sciences, Mo-hammed First University, Boulevard Mohamed VI, Oujda, Morocco
Biochemistry Department College of Science University of Jeddah, Jeddah, Saudi Arabia
Center of Data Science and Sustainable Technologies, INTI International University, Nilai, Malaysia
Department of Chemistry and Biochemistry, Faculty of Medicine and Pharmacy, Ibn Zohr University, Laayoune, Morocco

3 Control of citrus nematode Tylenchulus semipenetrans (Tylenchida: Tylenchulidae) using plant-based products under in vitro and in vivo conditions

Seyedeh Zohreh Asadi , Salar Jamali , Mohammad Ghadamyari , Vahid Mottaghitalab

Journal of Plant Protection Research | 2024 | vol. 64 | No 2 | 106-114 | DOI: 10.24425/jppr.2024.150246

Keywords: Artemisia annua citrus essential oil Melia azederach Tylenchulus semipenetrans

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Abstract

The citrus nematode (Tylenchulus semipentrans) is one of the most important parasitic nematodes affecting citrus trees, causing gradual decline and reduced yield. Potential risks, high costs and environmental consequences of chemical compounds have led researchers to explore non-chemical methods such as using plant-based products for nematode management. The present study was conducted to control citrus nematodes using essential oil and water extract of Artemisia annua and methanolic extract of Melia azederach under laboratory and greenhouse conditions. In vitro bioassays were carried out, and the effects on toxicity, mortality, and egg hatching were assessed. The highest in vitro nematistatic activity was recorded for 250 ppm of A. annua essential oil and 500 ppm of M. azederach methanol extract by 100% paralysis of nematodes after 48 h. Furthermore, the highest nematicidal activity of A. annua essential oil, aqueous extract and methanolic extract of M. azederach was recorded to be about 60−100%, 40−87% and 38−100%, respectively. Among all concentrations of M. azederach methanolic extract and high concentrations of A. annua essential oil and aqueous extract, the repellents and motility inhibitors for nematodes were found. The results of egg hatching showed that essential oil of A. annua at a concentration of 250 ppm had the greatest reduction of egg hatching. In a greenhouse experiment, all the treatments were found to be significantly effective against the citrus nematode population in soil and roots compared to the control. Maximum reduction was observed in 500 ppm of methanolic extract of Melia azederach. Growth parameters (plant height, fresh and dry shoot and root weight) increased compared to the control when treatments were applied. Based on the results, plants such as A. annua and M. azedarach are considered to be promising control agents for citrus nematodes. The results indicate that products derived from these plants may be potential candidates for formulating new nematicides suitable for sustainable nematode management, although field trials are still needed to demonstrate their effectiveness for commercial use.

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Authors and Affiliations

Seyedeh Zohreh Asadi

Salar Jamali

Mohammad Ghadamyari

Vahid Mottaghitalab

Plant Protection Department, Faculty of Agricultural Sciences, University of Guilan, Rasht 41635-1314, Iran
Textile Engineering Department, University of Guilan, Rasht 41635-1314, Iran

4 Light spectrum affects growth, metabolite profile, and resistance against fungal phytopathogens of Solanum lycopersicum L. seedlings

Alicja Tymoszuk , Dariusz Kulus , Jolanta Kowalska , Alicja Kulpińska , Dariusz Pańka , Małgorzata Jeske , Małgorzata Antkowiak

Journal of Plant Protection Research | 2024 | vol. 64 | No 2 | 115-126 | DOI: 10.24425/jppr.2024.150247

Keywords: LED light plant disease plant metabolites plant morphology tomatocultivation

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Abstract

Tomato is a widely cultivated and economically important crop worldwide. This study aimed to test the effect of light spectra used in indoor cultivation on the growth, biochemical profile, and resistance of Solanum lycopersicum ‘Bawole Serce’ seedlings against Alternaria alternata, Alternaria solani and Botrytis cinerea. During the phase of first leaf emergence, the seedlings were transferred to a semi-sterile growth room with a controlled environment (20°C, 18-h photoperiod, 50 μmol · m⁻² · s⁻¹ PPFD, 65% RH) for a 3-week cultivation period. Five light treatments differing in red/blue (R/B) light ratio were tested: I (LED tube; R/B 5.55), II (fluorescent tube; R/B 0.72), III (fluorescent tube; R/B 1.19), IV (LED panel; R/B 0.51), V (LED panel; R/B 0.20). The best parameters in terms of shoot length, shoot fresh and dry weights, and number of leaves were obtained in treatment I, in contrast to IV and V. Plants from treatments IV and V had the smallest leaf area, perimeter, vertical length, and horizontal width. As for the root system, the highest fresh weight, area, length of the longest root, total length, and the number of root tips and forks were found in treatments I and II. The least developed root systems were observed in IV and V. The greatest chlorophyll, carotenoids and anthocyanins accumulation was enhanced by treatment II. Treatments I−III stimulated the biosynthesis of phenolic compounds. The highest superoxide dismutase activity was detected in plants from treatments I and II. As for A. alternata and A. solani, the level of disease symptoms was significantly higher for treatments IV and V than for I-III. The highest/lowest level of B. cinerea infection was found in treatments II/I, respectively. The least susceptible to infection by all tested pathogens were leaves from treatment I. Light spectrum composition is of practical importance for tomato seedling production.

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Authors and Affiliations

Alicja Tymoszuk

Dariusz Kulus

Jolanta Kowalska

e-mail:

ORCID:

Alicja Kulpińska

Dariusz Pańka

Małgorzata Jeske

Małgorzata Antkowiak

Laboratory of Horticulture, Faculty of Agriculture and Biotechnology, Bydgoszcz University of Science and Technology, Bydgoszcz, Poland
Department of Organic Agriculture and Environmental Protection, Institute of Plant Protection – National Research Institute, Poznań, Poland
Department of Biology and Plant Protection, Faculty of Agriculture and Biotechnology, Bydgoszcz University of Science and Technology, Bydgoszcz, Poland

5 Toxicological, biological, and biochemical impacts of the egyptian lavender (Lavandula multifida L.) essential oil on two lepidopteran pests

Mona Awad , Moataz A.M. Moustafa , Nawal Abdulaziz Alfuhaid , Alia Amer , Fatma S. Ahmed

Journal of Plant Protection Research | 2024 | vol. 64 | No 2 | 127-138 | DOI: 10.24425/jppr.2024.150245

Keywords: Agrotis ipsilon essential oil Gas Chromatography-Mass Spectrometry (GC-MSlavender) Spodoptera littoralis

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Abstract

The use of essential oils as an eco-friendly tool in pest management stems from their natural origin and the presence of bioactive compounds that exhibit pesticidal properties, offering a sustainable alternative to synthetic chemical pesticides. This study explores the toxicity of Lavandula multifida (lavender) essential oil (EO), as a botanical pesticide against two widespread and destructive Noctuidae pests, Spodoptera littoralis (Boisd.) and Agrotis ipsilon (Hufnagel). GC-MS was employed to characterize 23 compounds in the EO, with 1,3,3-trimethyl-2-oxabicyclo [2.2.2] octane (eucalyptol) (39.84%), being the primary component. The leaf dipping technique was utilized to assess the toxicity of the EO to both insects. At 96 hours post-treatment, the LC₅₀ of lavender EO to S. littoralis and A. ipsilon larvae were 2.350 and 2.991 mg · ml^–1, respectively. Concerning its biological effect, both concentrations of the EO (LC₁₅ and LC₅₀) significantly shortened the duration of the larval (to 15.24 and 14.23 days) and pupal (to 11.19 and 10.55 days) stages of S. littoralis. Biochemical assays revealed that the LC50 of lavender EO significantly inhibited α-esterase activity in S. littoralis at 72- and 96 hours post-treatment (0.031 and 0.063 mmol · min^–1 · mg^–1), and A. ipsilon at 96 hours post-treatment (0.129 mmol · min^–1 · mg^–1 protein). Given its significant toxicological, biological, and biochemical effects on S. littoralis, it is suggested that lavender EO could be considered for use in integrated pest management strategies while ensuring its safe application to protect non-target organisms.

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Authors and Affiliations

Mona Awad

Moataz A.M. Moustafa

Nawal Abdulaziz Alfuhaid

Alia Amer

Fatma S. Ahmed

Economic Entomology and Pesticides Department, Faculty of Agriculture, Cairo University, 6 ElGamma Street, 12613 Giza, Egypt
Biology Department, College of Science and Humanities, Prince Sattam Bin Abdulziz University, 11942 Al-Kharj, Saudi Arabia
Medicinal and Aromatic Plants Department, Horticulture Research Institute, Agricultural Research Center, Agricultural Rese, 12556 Giza, Egypt

6 Molecular characterization of cotton leaf curl Multan beta-satellite occurance on chili plants in Multan, Pakistan

Hajra Azeem , Amjad Ali , Rashida Perveen , Ummad ud din Umar , Muhammad Zakria , Fatih Ölmez , Muhammad Usman Azeem

Journal of Plant Protection Research | 2024 | vol. 64 | No 2 | 139-148 | DOI: 10.24425/jppr.2024.150248

Keywords: begomovirus cotton leaf curl virus Geminiviridae phylogenetic analysis stunted growth

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Abstract

The prevalence of cotton leaf curl disease (CLCuD) has significantly hampered chili (Capsicum spp.) production, presenting a formidable challenge in Pakistan. During a chili field survey in 2018, distinct symptoms, including stunted growth, yellowing, and severe leaf curling, were observed on several plants. Subsequently, a comprehensive sampling effort was undertaken, collecting a total of 39 symptomatic samples from diverse locations across Multan, Punjab. The DNA extraction from these samples was conducted at the plant virology laboratory at Bahauddin Zakariya University, Multan, marking a crucial step in the investigation of this debilitating disease and its impact on chili production in the region. Molecular analysis with PCR using Av/Ac Core, Beta 01/02, and CLCuMuBF11/R33 primers confirmed begomovirus infection in chili plants. Positive amplification demonstrated a 71.79% infection rate, with 579 bp, 1.4 kb, and 481 bp amplicons for Av/Ac Core, Beta 01/02, and CLCuMuBF11/R33, respectively. Sequencing identified cotton leaf curl Multan beta-satellite (MT668934) infecting the chili plant. Effectively managing these begomoviruses is crucial to curbing their multiplication and protecting vital crops like chili. Addressing the distributions of beta-satellites in agricultural fields, particularly chili, is imperative to prevent further viral spread.

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Authors and Affiliations

Hajra Azeem

Amjad Ali

Rashida Perveen

Ummad ud din Umar

Muhammad Zakria

Fatih Ölmez

Muhammad Usman Azeem

Crop Diseases Research Institute, National Agricultural Research Centre, Islamabad, Pakistan, 45500 Islamabad, Pakistan; Faculty of Agricultural Sciences and Technology, Department of Plant Pathology, Bahauddin Zakariya University, 60800 Multan, Pakistan
Faculty of Agricultural Sciences and Technologies, Department of Plant Protection, Sivas University of Science and Technology, 58140 Sivas, Turkey
Faculty of Agricultural Sciences and Technology, Department of Plant Pathology, Bahauddin Zakariya University, 60800 Multan, Pakistan
Crop Diseases Research Institute, National Agricultural Research Centre, Islamabad, Pakistan, 45500 Islamabad, Pakistan
Department of Food Science and Technology, Bahauddin Zakariya University, 60000 Multan, Pakistan

7 Pantoea stewartii subsp. stewartii, the causative agent of Thai jackfruit’s bronzing disease and its possible host range in Vietnam

Vo T.N. Ha , Le K. Hoang , Pham K. Huyen

Journal of Plant Protection Research | 2024 | vol. 64 | No 2 | 149-157 | DOI: 10.24425/jppr.2024.150249

Keywords: bronzing of Thai jackfruit causal agent cross-infect host range Pantoeastewartii subsp. stewartii

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Abstract

The bronzing disease of Thai jackfruit (Artocarpus heterophyllus Lam.) has recently appeared in Vietnam, causing a significant loss for farmers, but its control method is still restricted. In this study, we identified pathogens based on morphological and molecular characterizations. A total of 25 bacterial isolates were isolated from diseased samples. The bacterium produces white or yellow pigment in culture, is gram-negative, slightly pleomorphic, non-motile, facultatively anaerobic, short-rod, and catalase-positive. It hydrolyzes gelatin and starch but not tween 80, and produces acid from glucose, sucrose, and lactose. The bacterium does not produce indole and does not produce hypersensitivity to tobacco. The results of sequencing of the encoded region of synthesis of capsular polysaccharide (cpsD) and pathogenicity-related genes HrpS confirmed that the causative agent is Pantoea stewartii subsp. stewartii. The pathogen’s possible host range could be traditional jackfruit varieties, fruits, and crops such as durian, longan, mango, tomatoes, broccoli, pumpkin, cucumber, corn, rice, sweet potatoes, water spinach, peanuts, and green beans. The P. stewartii subsp. stewartii could enter the host plant cell through open wounds or natural openings such as stomata. The results confirmed the presence of P. stewartii subsp. stewartii in Vietnam and suggest that the jackfruit tree should not be planted in plantations with these crops to prevent cross-contamination and the spread of pathogens.

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Authors and Affiliations

Vo T.N. Ha

Le K. Hoang

Pham K. Huyen

Plant Protection Department, Nong Lam University Ho Chi Minh City, Linh Trung Ward, Thu Duc District, Ho Chi Minh City 700000, Viet Nam

8 Potential molluscicidal activity of the aqueous extracts of some plants and their powders against terrestrial snail Monacha obstructa (L. Pfeiffer, 1842) under laboratory and field conditions

Mohamed M. Abo-Elwfa , Mahmoud M.A. Omar , Emad A. El-Shamy , Hesham A.M. Ibrahim

Journal of Plant Protection Research | 2024 | vol. 64 | No 2 | 158-164 | DOI: 10.24425/jppr.2024.150250

Keywords: Monacha obstructa pest management plant extracts Solanum nigrum the clover snail

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Abstract

As it is known that the excessive use of pesticides causes many environmental problems, the effects of four aqueous plant extracts and their powders [Solanum nigrum L., Withania somnifera (L.) Dunal, Salix mucronata Thunb. and Lawsonia inermis L.] were evaluated as natural molluscicides on the land snail Monacha obstructa (Family: Hygromiidae) under laboratory conditions. Three different bioassay methods were used: contact, leaf-dipping and bait techniques. The results indicated that, using all methods, S. Nigrum extract was the most toxic extract for the terrestrial snail M. obstructa. The contact technique of the tested plant extracts was the most effective method of application compared to other methods. Moreover, using plant extracts was better than using powders of these plants for controlling the terrestrial snail M. obstructa. In addition, the results indicated that the aqueous extract of S. nigrum gave the highest percentage of reduction in the snail population when assessed under field conditions. The obtained data showed that plant extracts were significantly effective against the terrestrial snail and could be used as alternatives to pesticides in integrated pest management.

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Authors and Affiliations

Mohamed M. Abo-Elwfa

Mahmoud M.A. Omar

Emad A. El-Shamy

Hesham A.M. Ibrahim

Department of Agricultural Zoology and Nematology, Faculty of Agriculture, Al‑Azhar University, Assiut, 71524, Assiut, Egypt

9 Assessment of the insecticidal efficacy of ethanol extract of Millettia pachyloba Drake leaves against Plutella xylostella Linnaeus moth

Thi Phuong Nhung Tran , Le Pham Tan Quoc

Journal of Plant Protection Research | 2024 | vol. 64 | No 2 | 165-177 | DOI: 10.24425/jppr.2024.150251

Keywords: biopesticide Brassica juncea Millettia pachyloba pest management Plutella xylostella

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Abstract

Plutella xylostella (L.), a menacing threat to cruciferous crops, exhibits cross-resistance to various chemical agents. The exploration of plant-derived insecticides emerges as an intervention strategy for the successful management of P. xylostella. Millettia pachyloba Drake is renowned as a traditional remedy for diverse health issues and has insecticidal properties. Experimental investigations in both laboratory and greenhouse settings utilized M. pachyloba extract (EMPE) at concentrations ranging from 2 to 10% (w/v). The objectives included inducing toxicity and controlling P. xylostella larvae effectively, assessing nutritional impacts through parameters like relative consumption rate (RCR), relative growth rate of larvae (RGR), efficiency of conversion of digested food (ECD), efficiency of conversion of ingested food (ECI), approximate digestibility (AD), and assimilation ratio (AR), and evaluating leaf damage inflicted by P. xylostella larvae on Brassica juncea. In the laboratory, the application of EMPE on P. xylostella larvae and pupae for 24, 48, and 72 hours yielded markedly higher mortality rates than the water-treated control (p < 0.05). Significant reductions in RGR, RCR, ECD, ECI, AD, and AR were evident throughout the larval stage (p < 0.05). In the greenhouse, EMPE treatments demonstrated notable differences from the water control treatment. On the 15th day of treatment, the EMPE treatment at 10% (w/v) exhibited the highest mortality rate (p < 0.05). Significantly reduced leaf damage was observed with EMPE treatments, displaying an inverse correlation with escalating concentrations. Particularly, the highest enhancement across all surveyed parameters was observed in the EMPE 10% (w/v) treatment, which was comparable to the positive control with fipronil (p > 0.05). Noteworthy differences in damage reduction percentage (DRP) were identified between EMPE contact treatments and the water control group (p < 0.05), indicating the promising potential of Millettia pachyloba extract for pest control.

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Authors and Affiliations

Thi Phuong Nhung Tran

Le Pham Tan Quoc

Institute of Biotechnology and Food Technology, Industrial University of Ho Chi Minh City, 12 Nguyen Van Bao street, 700000, Ho Chi Minh City, Viet Nam

10 Distribution and survival of the predatory mite Blattisocius mali on cucumber leaves with the addition of bran, yeast and pollen

Katarzyna Michalska , Klaudia Ziółkowska , Aleksandra Radziejewska , Marcin Studnicki , Muhammad Arslan Ibrahim

Journal of Plant Protection Research | 2024 | vol. 64 | No 2 | 178-188 | DOI: 10.24425/jppr.2024.150244

Keywords: biological control cannibalism starvation suplementary diet survival

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Abstract

Biological control has a special position in sustainable agriculture that requires continuous exploration and diversification in bio-agents to cope with emerging crop pests. Blattisocius mali is a promising biological control agent against some acarid mites, nematodes and moth pests. This study aimed to examine factors that could increase survival and diminish dispersal of B. mali deprived of its prey, the mold mite Tyrophagus putrescentiae, from cucumber plants. The impact of the presence of males on starving females’ lifespans and the influence of different substrates, i.e., wheat bran, dry yeast pellets, and cattail pollen, on the distribution and survival of starving females in groups with males were examined. Experiments were performed on cucumber leaf platforms in Petri dishes filled with water. The results showed that females lived longer and a lower percentage drowned in water when accompanied by males. On the platforms with the addition of a substrate, the mites mainly stayed within the substrate, and eggs were only recorded in the substrate. They clearly preferred bran over pollen or pollen + yeast pellet aggregations. However, the quality of the substrate deteriorated within the first days, and some mites died of entrapment in the substrates. On the 3rd day, the lowest mean percentage of live individuals was observed on platforms with yeast + pollen (54.4%) followed by pollen (68.9%) alone. At that time, females also stopped laying eggs, and cannibalism towards hatched larvae and adults was observed. By the end of the experiment, 54.67% of the mites had been found dead on the leaf surface, and none of the substrates had significantly influenced their lifespan. The females lived on average 8.19 days and the males 5.06 days. The obtained results are discussed in the context of potential application of B. mali in biological control strategies.

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Authors and Affiliations

Katarzyna Michalska

Klaudia Ziółkowska

Aleksandra Radziejewska

Marcin Studnicki

Muhammad Arslan Ibrahim

Department of Plant Protection, Warsaw University of Life Sciences, Warsaw, Poland

11 The activity of Trichoderma spp. culture filtrate to control Phelipanche aegyptiaca infection in tomato

Farnaz Jalali , Saeed Abbasi , Hooman Salari

Journal of Plant Protection Research | 2024 | vol. 64 | No 2 | 189-199 | DOI: 10.24425/jppr.2024.150252

Keywords: biocontrol beneficial fungi broomrape mycoherbicides parasitic plants weed management

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Abstract

Two independent pot experiments were conducted to evaluate the potential of two different application methods for culture filtrates of 10 Trichoderma spp. strains to reduce infection of Phelipanche aegyptiaca in tomatoes. In the first method (foliar spray), seedlings were foliar sprayed three times with culture filtrate of each Trichoderma spp. strains pre- and posttransplanting. In the second method (soil drench), these culture filtrates were incorporated into the top 5 cm of the soil surface during transplantation. Foliar sprays of T33, T60, and T36 significantly reduced the progression of P. aegyptiaca infection throughout the growing period (85 days). The number of P. aegyptiacaʹs aboveground stalks and underground juveniles was also significantly reduced (83 and 66%) in T33-treated plants at the end of the experiment, while the fresh and dry weights of tomato fruits was significantly increased (86% and 90%). In the second approach, T66, T33, T35, T36, and T67 strains caused a significant reduction in the progression of P. aegyptiaca infection on tomatoes during the same period. The fresh and dry weights of stalks and attached juveniles of P. aegyptiaca in T66-treated plants were significantly reduced by 77, 52, 75, and 49%, respectively, compared to the control. The conclusion showed that T. virens T33 culture filtrate as foliar spray through some kind of induced systemic resistance (ISR) and T. brevicompactum T66 culture filtrate as soil drench can be used as natural bioherbicides to control P. aegyptiaca in tomatoes.

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Authors and Affiliations

Farnaz Jalali

Saeed Abbasi

Hooman Salari

Plant Protection Department, Razi University, 6714414971, Kermanshah, Iran
Plant Production and Genetics Department, Razi University, 6714414971, Kermanshah, Iran

12 Semisynthetic compounds for controlling Colletotrichum lindemuthianum on bean seeds

Gisele Fabiana Zabot , Viviana Gaviria-Hernández , Cândida Renata Jacobsen de Farias , Giovani Leone Zabot

Journal of Plant Protection Research | 2024 | vol. 64 | No 2 | 200-208 | DOI: 10.24425/jppr.2024.150253

Keywords: anthracnose Citral Phenyl S Citral Phenyl Se Citronellal semisynthetic compounds

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Abstract

Anthracnose caused by Colletotrichum lindemuthianum is one of the main diseases that affect the bean crop. The use of semisynthetic compounds for controlling anthracnose aims at providing a higher balance to the ecosystem and a lower environmental impact. Based on this context, the objective of this work was: a) to carry out the prospection of compounds such as Phenyl S Citral, Phenyl Se Citronellal, and Citral at concentrations of 1, 0.5, 0.25, 0.125, 0.0625, 0.0312, 0.0156, 0.0078, and 0.0039%, which were modified from the essential oil of citronella and lemongrass, for controlling C. lindemuthianum; b) to evaluate the initial performance of seedlings and treat the incidence of C. lindemuthianum in bean seeds with Phenyl S Citral and Phenyl Se Citronellal at concentrations of 0.125 and 0.0625%. Phenyl Se Citronellal at 0.5% controlled 100% of mycelial growth and Phenyl S Citral at 0.5 and 1% controlled more than 50% of mycelial growth of C. lindemuthianum. The treatment with Phenyl S Citral and Phenyl Se Citronellal did not affect the physiological quality of bean seeds while increasing seedling development when using the 0.0625% concentration of Phenyl Se Citronellal. Treatment with Phenyl Se Citronellal at both concentrations decreased the incidence of C. lindemuthianum infection.

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Authors and Affiliations

Gisele Fabiana Zabot

Viviana Gaviria-Hernández

Cândida Renata Jacobsen de Farias

Giovani Leone Zabot

e-mail:

ORCID:

Department of Crop Protection, Federal University of Pelotas, Jardim América, 96010-900, Pelotas, Brazil
Laboratory of Agroindustrial Processes Engineering (LAPE), Federal University of Santa Maria (UFSM), Taufik Germano, 96503-205, Cachoeira do Sul, Brazil

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