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Effectiveness of biological products for control of the most significant mycoses on potato crops
- Authors: Pakina E.N.1, Shkurkin S.I.2, Mukhina M.T.2
-
Affiliations:
- RUDN University
- Pryanishnikov Institute of Agrochemistry
- Issue: Vol 18, No 4 (2023): Pesticides. Looking to the future
- Pages: 501-507
- Section: Pesticides. Looking to the future
- URL: https://agrojournal.rudn.ru/agronomy/article/view/19952
- DOI: https://doi.org/10.22363/2312-797X-2023-18-4-501-507
- EDN: https://elibrary.ru/LDMWUJ
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Abstract
Experiments on comparative assessment of effectiveness of bioagents to control the most significant fungal diseases were carried out on crops of potato breeding line in the Zernograd district, Rostov region. Biofungicide Metabakterin, WP based on Methylobacterium extorquens NVD VKM B-2879D + Validamycin Streptomyces hygroscopicus subsp. limoneus VKPM AC-1966 + Bacillus subtilis VKPM B-2918 IPM 215 and biofungicide Vitaplan based on Bacillus subtilis , strain VKM-B-2604D + Bacillus subtilis , strain VKM-B-2605D were studied in the research. The results showed that Metabakterin, WP at the rate of 80 g/ha was the most effective for control of early blight, late blight, fusarium dry rot and rhizoctonia canker on potatoes, while protection period of the biofungicide against these fungal diseases ranged from 19 to 27 days. It was noted that application rate of 80 g/ha of Metabakterin, WP provided the maximum increase in potato yield.
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Introduction
Potato occupies one of the first places among crops in dry matter production per unit area, while its tubers are a universal product and the main source of vitamin C. The importance of potatoes as one of the main food crops of the Russian Federation can hardly be overestimated; the average annual consumption of this crop only for food is estimated at 15 million tons. However, a large share of the market today is represented by foreign cultivars, especially for seed planting material, which is a serious challenge to the country’s food security. Therefore, according to the plan of the Ministry of Agriculture of the Russian Federation, half of seed potatoes should be produced in Russia by 2025. Among the tasks of modern potato breeding, in addition to creating highly productive varieties with high taste qualities, the seed production program indicates the mandatory adaptability of varieties to biotic and abiotic factors when cultivated in various climatic conditions [1, 2].
The problem of adapting planting material obtained in vitro to open ground conditions is not only in successful survival of plants, but also in their ability to withstand stress caused by a complex of secondary phytopathogens, among which the most harmful to potatoes are early blight, late blight, fusarium dry rot and rhizoctonia canker [1] [3–6]. Chemical fungicides, conventionally used to control pathogenic microbiota, often create additional stress for young plants [7, 8], while in order to preserve agronomic traits of crop, especially in selective crops, it is preferable to use non-chemical methods for controlling phytopathogens to reduce the pesticide load on plants and improve physiological and biochemical parameters of the final product [2, 9, 10].
The purpose of the study was to evaluate the effectiveness of Metabakterin, WP and Vitaplan for biological control of early blight, late blight, fusarium dry rot and rhizoctonia canker on potato breeding lines and their influence on crop yield formation.
Materials and methods
In controlling mycoses on potatoes, the most commonly used non-chemical product is Vitaplan based on Bacillus subtilis, strain VKM-B-2604D + Bacillus subtilis, strain VKM-B-2605D at a recommended application rate of 20 g/ha. Vitaplan and Metabakterin, WP based on Methylobacterium extorquens NVD VKM B-2879D + Validamycin Streptomyces hygroscopicus subsp. limoneus VKPM AC-1966 + Bacillus subtilis VKPM V‑2918 IPM 215 were used when developing a system for controlling the most significant diseases on potatoes in open ground conditions.
To evaluate the effectiveness of bioagents Metabakterin, WP and Vitaplan, the studies were carried out on crops of potato breeding line in the Zernograd district of the Rostov region. The experiment consisted of four replications of four experimental plots (25 m[2]) with a sequential arrangement in accordance with the Guidelines for Registration Testing of Fungicides in Agriculture 2.
Pre-planting treatment of tubers was carried out with Metabakterin, WP based on active ingridient Methylobacterium extorquens NVD VKM B-2879D + Validamycin Streptomyces hygroscopicus subsp. limoneus VKPM AC-1966 + Bacillus subtilis VKPM V-2918 IPM 215 with a titer concentration of at least 1010 CFU/g + 0.5 g/kg + titer of at least 1010 CFU/g at the rate of 15 g/t and 20 g/t. Subsequent treatments of vegetative plants were carried out by spraying three times during the growing season after the appearance of 2–4 true leaves and then with an interval of 12–14 days at the rate of 40+40+40 g/ha and 80+80+80 g/ha. Pre-planting treatment of tubers with Vitaplan titer 1010 + 1010 CFU/g Bacillus subtilis, strain VKM–V-2604D + Bacillus subtilis, strain VKM–V-2605D was carried out at a rate of 20 g/t, followed by three treatments of vegetative plants after the appearance of 2–4 true leaves and then with an interval of 12–14 days at the rate of 20+20+20 g/ha. Treatments with the biofungicides were carried out using a backpack pump sprayer “Zhuk Optima” with a spray mix volume rate of 300 L/ha (Table 1).
Table 1. Scheme of the experiment to evaluate effectiveness of Metabakterin, WP
Variant | Treatment | Application rate |
1 | Metabakterin, WP | 15 g/t + (40 + 40 + 40 g/ha) |
2 | Metabakterin, WP | 20 g/t + (80 + 80 + 80 g/ha) |
3 | Vitaplan, titer 1010 +1010 CFU/g Bacillus subtilis, strain VKM-В-2604D + Bacillus subtilis, strain VKM-В-2605D | 20 g/t + (20 + 20 g/ha) |
4 | Control (no treatment) | — |
Potato harvesting was carried out manually from 10 plants, 3 rows of each plot. The results of field experiments, as well as harvest data, were statistically analyzed using the MS Excel.
Results and discussion
The following fungal diseases were found on potato crops: early blight (Alternaria sp.), late blight (Phytophthora sp.), fusarium dry rot (Fusarium sp.) and rhizoctonia canker (Rhizoctonia sp.), which are typical mycosis for the crop [2, 4, 5, 8, 11–14]. Biological efficiency of Metabakterin, WP at the rate of 40 g/ha against Alternaria was 78.1 %. At the same time, increase in the application rate to 80 g/ha increased efficiency to 81.2 %. Vitaplan at the rate of 20 g/ha controlled the development of Alternaria blight at 77.5 %. In addition to the bacterium Bacillus subtilis, which is the main active component of Vitaplan, Metabakterin, WP also includes Methylobacterium extorquens and Streptomyces hygroscopicus subsp., which ensures a higher effectiveness of the biofungicide. A complex of two bacterial genera and an actinomycete is capable of suppressing phytopathogenic microbiota to a greater extent than monocomponent biological products.
To control late blight, Metabakterin, WP at the rate of 40 g/ha showed 73.2 % efficiency, increase in the application rate to 80 g/ha led to increase in efficiency to 80.3 %. At the same time, efficiency of Vitaplan at the rate of 20 g/ha was at the level of 71.8 %.
Efficiency of Metabakterin, WP against Fusarium at a consumption rate of 40 g/ha was 69.3 %. Thus, it was close to Vitaplan application at the rate of 20 g/ha, wich efficiency was 68.2 %. Further increasing the application rate to 80 g/ha did not lead to a significant increase in efficiency, amounting to 70.2 %.
In controlling rhizoctonia canker, Metabakterin, WP at the rate of 40 g/ha showed 67.3…68.2 % efficiency, which was lower compared to Vitaplan 20 g/ha with 68.4…69.38 % efficiency. When application rate was increased to 80 g/ha, effectiveness of Metabakterin, WP increased to 71.4…73.2 %. (Tables 2 and 3).
The yield increase obtained in the variant with Metabakterin, WP at the rate of 40 g/ha was 10.9 %, increasing the application rate to 80 g/ha provided 13.9 % yield increase, using Vitaplan increased yield by 11.7 % compared to the control (Table 4).
Table 2. Efficacy of Metabakterin, WP against early blight, late blight, fusarium dry rot canker on potato breeding line, Rostov region, 2023
Variant | Application rate, L/ha | Number of treatments | Dates of treatments: 5 and 27 May; 10 and 24 June | |||||||||||||
Early blight | Late blight | Fusarium dry rot | ||||||||||||||
05.06 | 15.06. | 25.06. | 15.06. | 25.06. | 25.06. | 05.07 | ||||||||||
| Progression, % | Efficacy, % | Progression, % | Efficacy, % | Progression, % | Efficacy, % | Progression, % | Efficacy, % | Progression, % | Efficacy, % | Progression, % | Efficacy, % | Progression, % | Efficacy, % | |||
Metabakterin, WP (15 g/t + (40+40+40 g/ha) | 40 g/ha | 4 | 6.8 | 63.8 | 9.4 | 62.8 | 7.6 | 78.1 | 4.2 | 66.9 | 5.6 | 73.2 | 6.2 | 70.9 | 9.3 | 69.3 |
Metabakterin, WP (20 g/t + (80+80+80 g/ha) | 80 g/ha | 4 | 5.6 | 70.2 | 8.0 | 68.4 | 6.5 | 81.2 | 2.4 | 81.1 | 4.1 | 80.3 | 5.5 | 74.2 | 9.0 | 70.2 |
Vitaplan, titer 1010 +1010 CFU/g Bacillus subtilis, strain VKM-В-2604D + + Bacillus subtilis, strain VKM-В-2605D | 20 g/ha | 4 | 5.8 | 69.1 | 8.3 | 67.2 | 7.8 | 77.5 | 3.6 | 71.6 | 5.9 | 71.8 | 6.1 | 71.4 | 9.6 | 68.2 |
Control (without treatment) | — | — | 18.8 | — | 25.3 | — | 34.6 | — | 12.7 | — | 20.9 | — | 21.3 | — | 30.2 | — |
Table 3. Efficacy of Metabakterin, WP against rhizoctonia canker on potato breeding line, Rostov region, 2023
Variant | Application rate, L/ha | Number of treatments | Dates of treatments: 5 and 27 May; 10 and 24 June | |||
Rhizoctonia canker | ||||||
25.06 | 05.07 | |||||
Progression, % | Efficacy, % | Progression, % | Efficacy, % | |||
Metabakterin, WP (15 g/t + (40+40+40 g/ha) | 40 g/ha | 4 | 6.4 | 67.3 | 10.7 | 68.2 |
Metabakterin, WP (20 g/t + (80+80+80 g/ha) | 80 g/ha | 4 | 5.6 | 71.4 | 9.0 | 73.2 |
Vitaplan, titer 1010 +1010 CFU/g Bacillus subtilis, strain VKM-В-2604D + Bacillus subtilis, strain VKM-В-2605D | 20 g/ha | 4 | 6.2 | 68.4 | 10.3 | 69.3 |
Control (without treatment) | — | — | 19.6 | — | 33.6 | — |
Table 4. Productivity of potato breeding line after application of Metabakterin, WP (Rostov region, 2023)
Variants | Productivity by replications, t/ha | Average productivity | ||||
1 | 2 | 3 | 4 | t/ha | % to control | |
Metabakterin, WP (15 g/t + (40+40+40 g/ha) | 25.0 | 25.8 | 25.8 | 25.9 | 25.6 | 110.9 |
Metabakterin, WP (20 g/t + (80+80+80 g/ha) | 23.9 | 27.2 | 28.4 | 25.8 | 26.3 | 113.9 |
Vitaplan, titer 1010 +1010 CFU/g | 23.8 | 25.5 | 27.8 | 26.1 | 25.8 | 111.7 |
Control (without treatment) | 20.0 | 23.1 | 24.5 | 24.8 | 23.1 | 100 |
LSD(05) % = 2.59 | ||||||
Conclusions
Results of the experimental comparison of Metabakterin, WP and Vitaplan effectiveness for control of early blight, late blight, fusarium dry rot, rhizoctonia canker on crops of potato breeding line and their influence on productivity led to the following conclusions:
- use of Metabacterin, WP biofungicide at the rate of 80 g/ha provides the maximum increase in potato yield;
- protection period of Metabakterin, WP against early blight, late blight, fusarium dry rot and rhizoctonia canker amounts 19, 22, 21 and 27 days;
- due to multicomponent composition, Metabakterin, WP at the rate of 80 g/ha is most effective for controlling early blight, late blight, fusarium dry rot and rhizoctonia canker on potatoes.
1 Gannibal F.B. Monitoring al’ternariozov sel’skokhozyaistvennykh kul’tur i identifikatsiya gribov roda Alternaria [Monitoring of Alternaria diseases of agricultural crops and identification of fungi of the genus Alternaria]. Saint- Petersburg; 2011. (In Russ.).
2 Dolzhenko VI. Metodicheskie ukazaniya po registratsionnym ispytaniyam fungitsidov v sel’skom khozyaistve: metodicheskoe posobie [Guidelines for registration testing of fungicides in agriculture]. Saint- Petersburg; 2011. (In Russ.).
About the authors
Elena N. Pakina
RUDN University
Email: e-pakina@yandex.ru
ORCID iD: 0000-0001-6493-6121
Doctor of Agricultural Sciences, Professor, Agrobiotechnological Department, Agrarian and Technological Institute
8/2 Miklukho-Maklaya st., Moscow, 117198, Russian FederationSergey I. Shkurkin
Pryanishnikov Institute of Agrochemistry
Email: elgen@mail.ru
ORCID iD: 0000-0002-7123-4213
Candidate of Legal Sciences, Director
31a Pryanishnikova st., Moscow, 127434, Russian FederationMaria T. Mukhina
Pryanishnikov Institute of Agrochemistry
Author for correspondence.
Email: mtmasm@mail.ru
ORCID iD: 0009-0006-7901-6858
Candidate of Agricultural Sciences, Head of the Laboratory for Testing Elements of Agricultural Technologies, Agrochemicals and Pesticides
31a Pryanishnikova st., Moscow, 127434, Russian FederationReferences
- Zeiruk VN, Glez VM. Pre-sowing seed material preparation and planting of potatoes. Plant protection and quarantine. 2010;(2):61–63. (In Russ.).
- Osipov V, Zhevora S, Yanushkina N. Efficiency of potato production: analysis of variation and differentiation of regions of the Russian Federation. IOP Conference Series: Earth and Environmental Science. 2019;274:012060. doi: 10.1088/1755–1315/274/1/012060
- Hannibal PB. Species of the genus Alternaria found in Russia and in some neighboring territories. Mycology and Phytopathology. 2015;49(6):374–385. (In Russ.).
- Bradshaw NJ. Report of the fungicide sub-group: Discussion of potato early and late blight fungicides, their properties & characteristics and harmonised protocols for evaluating these. PPO-Special Report. 2007;(12):107–111.
- Elansky SN, Pobedinskaya MA, Kokaeva LY, Statsyuk NV, Alexandrova AV. Molecular identification of the species composition of Russian isolates of pathogens, causing early blight of potato and tomato. PPOSpecial Report. 2012;(15):151–156.
- Anisimov BV, Zebrin SN, Zeiruk VN. Dry and soft rot of tubers and their control in potato seed production. Plant protection and quarantine. 2017;(5):30–35. (In Russ.).
- Vlasenko NG, Bokina IG. Ecologization of plant protection in conditions of intensification. Chief Agronomist. 2018:(9):7–10. (In Russ.).
- Abbas MF, Naz F, Irshad G. Important fungal diseases of potato and their management — a brief review. Mycopath. 2013;11(1):45–50.
- Nadykta VD. main results of ARRIBPP’ research on biological plant protection. In: Biological plant protection — the basis for stabilization of agroecosystems: conference proceedings. Krasnodar; 2012. p.20–22. (In Russ.).
- Pavlyushin VA. Biologization of plant protection — a necessary condition for the development of crop production. Chief Agronomist. 2018;(7):6–9. (In Russ.).
- Cheremisin AI. The effectiveness of the use of protective equipment in cultivation of seed potatoes. In: Potato growing: conference proceedings. Minsk; 2007. p.379–384. (In Russ.).
- Khalaeva VI, Volchkevich IG, Sereda GM, Konopatskaya MV. Effectiveness of fungicides to protect potatoes against late blight. Plant protection. 2020;(44):115–124. (In Russ.).
- Özer G, Bayraktar H. Characterization and sensitivity to fungicides of Rhizoctonia spp. recovered from potato plants in Bolu, Turkey. Journal of Phytopathology. 2015;163(1):11–18. doi: 10.1111/jph.12275
- Widmark AK, Andersson B, Cassel-Lundhagen A, Sandström M, Yuen JE. Phytophthora infestans in a single field in southwest Sweden early in spring: symptoms, spatial distribution and genotypic variation. Plant Pathology. 2007;56(4):473–579. doi: 10.1111/j.1365‑3059.2007.01618.x
