RU2614261C1 - Method of adaptation of regenerated strawberry plants - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention is a method of adapting the regenerated plants of strawberries, including the adaptation phase where the regenerated plants of strawberry large-fruited in the period of adaptation to moisturize three times during the period at regular intervals freshly prepared aqueous suspension of silicon-mechanocomposite based on rice husk and green tea prepared by mixing siliceous mechanocomposite and room temperature water in a concentration of 3 g/l and subsequent infusion for 1 hour at room temperature, and in between is moistened with distilled water.

EFFECT: invention can successfully acclimate strawberries macrocarpa through feeding microplants stage adaptation siliceous mechanocomposites based on rice husk and green tea.

1 tbl

Description

The invention relates to biotechnology and agriculture, namely to horticulture and nursery, and can be used to prepare regenerated plants of strawberries grown in vitro, to adapt to ex vitro conditions.

It is known that one of the most common crops in horticulture is large-fruited strawberries, also called pineapple or horticultural (Fragaria x ananassa Duch.), And the use of clonal micropropagation of this plant allows you to get not only improved planting material, but also significantly accelerate the process of commercial propagation of strawberry varieties large fruited. In vitro cultivation conditions are characterized by constant high air humidity (reaching 100%), low light and heterotrophic type of nutrition. Therefore, the ex vitro adaptation period is a stressful stage for microplants, since they need to adapt to normal environmental conditions, in which the optimal parameters for the development of the aerial part and root system influence the success of plant adaptation. To successfully pass this stressful stage, it is necessary to search for new growth and development regulators that provide quick and effective survival of planting material.

It is known that at the stage of adaptation, microplants are fed a solution of mineral salts according to the recipe Murasige and Skoog (1. Agricultural biotechnology: Textbook / V.S. Shevelukha, E.A. Kalashnikova, E.Z. Kochieva and others; edited by V. S. Sheveluhi. - 3rd ed., Revision and additional - M .: Higher school, 2008. - S. 154-155). This solution has a well-balanced composition of nutrients, but it does not take into account the need for balancing on the necessary element - silicon.

According to modern ideas, the nutrition of organisms should be balanced in silicon, and for this purpose a mechanocomposite based on rice husk and green tea containing a water-soluble and bioavailable amorphous silicon dioxide (2. Pat. RF No. 2438344, class A23K 1 / 00, A23K 1/16, published on January 10, 2012). The product is fodder flour obtained by mechanochemical treatment in activator mills according to the aforementioned patent (2); hereinafter, for brevity, we will call the mechanocomposite. This mechanocomposite contains water-soluble silicon compounds (in terms of silicon) in the amount of 9-12 μg / ml in the test suspension when testing the quality of the mechanocomposite according to (2).

The meaning of the term "mechanocomposite" is to emphasize the fundamental differences in the structure and properties of powder materials - mixed systems formed during processing in special activator mills. A distinctive feature of a mechanocomposite is the presence of a developed, with special properties, phase interface of plant materials and a reagent and increased reactivity associated with this effect (3. Mechanocomposites - precursors for creating materials with new properties / [A.I. Ancharov et al.]; Edited by OI Lomovsky; Russian Academy of Sciences, Siberian Branch, Institute of Solid State Chemistry and Mechanochemistry [et al.], Novosibirsk: Publishing House SB RAS, 2010. - (Integration projects of the SB RAS; issue 26). - P. 5).

However, the specified mechanocomposite based on rice husks and green tea was tested on animals, but was not tested for feeding microplants of large-fruited strawberries. In addition, it is not obvious that this mechanocomposite is able to give a positive effect specifically for microplants of large-fruited strawberries and precisely at the stage of adaptation due to the unconventional composition and method of producing the composite (composition: cellulose and hemicellulose, water-soluble silicon, green tea catechins; production method: mechanochemical ), and due to the complexity of the adaptation stage and many factors (temperature, humidity, lighting) and phenomena that matter (for example, the stomatal activity is disturbed or not disturbed apparatus, as a result of which large amounts of water are lost or death of plants; or not, the mechanocomposite stimulates the growth of the aerial part of regenerated plants; stimulates or not the mechanocomposite the state of the root system of regenerated plants; the result depends or does not depend on the genotype, i.e. varieties of strawberries large-fruited). T.O. without evidence - the results of special studies - the positive effect of the use of this mechanocomposite for the purposes of the present invention is not obvious to specialists. This evidence - the results of special studies - is provided in the present invention below.

The well-known "Method for producing planting material of strawberries in tissue culture" (4. Pat. RF №2007072, class A01N / 00, publ. 02.15.1994), according to which, with microclonal propagation of strawberries, rooting and adaptation of shoots is carried out simultaneously in cultivation vessels which, before coating with a heat-shrink film, are additionally covered with plugs made of autoclaved perlite.

A disadvantage of the known technical solution, from the point of view of the present invention, is that a silicon-containing preparation was not used at the stage of adaptation for feeding microplants, and the stage of adaptation itself was not isolated, since rooting and adaptation of shoots were carried out simultaneously in cultivation vessels; as a result, the overall survival rate of plants turned out to be small (87% in the field, in greenhouses - 75-80%).

The closest technical solution chosen for the prototype is “A method for preparing garden strawberry plants (Fragaria L.) propagated in vitro for ex vitro cultivation conditions” (5. Pat. RF No. 2302106, class A01H / 00, publ. 10.07 .2007), which includes the preparation of plants in vitro, that is, the adaptation stage with specially selected conditions: the plants are kept in the dark, at a temperature of 1 to 10 ° C, on an agarized nutrient medium with 4-10% sucrose for 20- 60 days, after which it is transferred to the soil substrate.

In the known technical solution, rooting and adaptation of the shoots is not carried out simultaneously, but sequentially, that is, the adaptation stage is distinguished (so that the survival rate of plants planted in the soil becomes no lower than 95%), however, the disadvantage of the known technical solution, from the point of view of the present invention, is that at the stage of adaptation, a silicon-containing preparation was not used for feeding microplants (ensuring survival rate not lower than 99%).

The problem solved by the claimed technical solution is to improve the adaptation of regenerated plants of wild strawberries due to the feeding of micro-plants at the stage of adaptation with a silicon-containing preparation.

The problem is solved thanks to the claimed method of adaptation of strawberry regenerated plants, including an adaptation step in which regenerated plants of large-fruited strawberries during the adaptation period are moistened three times at regular intervals by a freshly prepared aqueous suspension of a silicon-containing mechanocomposite based on rice husk and green tea prepared by stirring mechanocomposite and water at room temperature at a concentration of 3 g / l and subsequent infusion for 1 hour at room temperature temperature, and in between moisturize with distilled water.

The positive effect of silicon on the growth of the aboveground organs of plants can be explained by increased phosphorylation of sugars, which in turn increases the energy supply for metabolic processes and sugar synthesis (6. Adams F. Interaction of phosphorus with other elements in soil and in plants // Proc. Symp. The Role of Phosphorus in Agriculture. Am. Soc. Agron., Madison, WI, 1980 .-- P. 655). The positive effect of silicon on the development of the root system of plants can be explained by the fact that silicon deficiency is one of the limiting factors in the development of the root system of plants (7. Kolesnikov MP, Forms of silicon in plants // Uspekhi Biologicheskoi Khimii, 2001. - T. 41. - S. 301-332; 8. Savant NK, Snyder GH, Datnoff LE Silicon management and sustainable rice production // Adv. Agron., 1997. - V. 58. - P. 158-199).

The inventive method and research of its results was carried out on the basis of the biotechnology laboratory of the Central Statistical Bureau of the SB RAS (Novosibirsk). The object was regenerated plants of Fragaria x ananassa Duch. from the collection of the Central Scientific Library System SB RAS, obtained by the method of clonal micropropagation at the age of four months The following varieties and hybrids were used: “Sunny Glade”, “Tsaritsa”, “Smile of June”, hybrid “5-90-21”, “Borovitskaya” and “Festivalnaya”. The selection of these varieties is due to the prospect of their use in Western Siberia due to the increased resistance to biotic and abiotic environmental factors.

A mechanocomposite based on rice husk and green tea was made at the Institute of Chemical Technology and Chemical Technology SB RAS according to (2).

Statistical processing of experimental data was performed using the Statistica program for Windows, version 6.1 of the software StatSoft, Inc. The experimental data were checked for compliance with the normal distribution. For each indicator, mean values and standard errors of the mean were calculated. Since the obtained results did not obey the normal distribution, the nonparametric Mann-Whitney U-test was used to identify significant differences between the parameters in the control and experimental versions. Differences were considered significant when the significance level reached p≤0.05.

The implementation of the proposed method is shown in the examples.

Example 1 (control: without mechanocomposite)

концентрации стандартных компонентов среды по прописи Мурасиге и Скуга. Под каждое растение вносили 5 мл рабочего раствора путем полива. Опыты проводили в двухкратной повторности, в каждом варианте было использовано не менее 30 регенерантов. С целью предотвращения обезвоживания первые 10 суток растения находились в микропарнике (влажность 80-90%), затем их выращивали в обычных условиях, опрыскивая водой два раза в сутки. Полив растворами осуществляли трижды за этап через равные промежутки времени, в промежутках субстрат увлажняли дистиллированной водой. Продолжительность данного адаптационного периода составила 4 недели, при 16-часовом фотопериоде, температуре 23-25°С и освещенности 2-3 клк. Приживаемость растений фиксировали при появлении новых листьев в конце периода. Под приживаемостью растений понимали отношение числа укорененных растений-регенерантов к фактически высаженному числу, выраженное в процентах. Через 4 недели растения извлекали из культуральных сосудов и измеряли следующие ростовые параметры: количество листьев, количество корней, высоту розетки, длину корневой системы, определяли величину прироста данных показателей за исследуемый период.When growing plants in vitro, standard cultivation techniques were used. Used medium for the prescription Murashige and Skoog with pH = 5.6-5.8. Cultivation was carried out under conditions of a 16-hour photoperiod, at a temperature of 23-24 ° C and illumination of 3-4 cells. The shoots were multiplied by the method of activation of axillary meristems of growth shoots. Cytokinin 6-benzylaminopurin at concentrations of 0.25-2.0 mg / L was used as an inducer of shoot formation. Subculture was carried out after 25-30 days. Microplants were rooted in agarized hormone-free nutrient medium according to the recipe Murashige and Skoog with half the content of macro- and micronutrients and low in sucrose (15 g / l). For the experiments, regenerants were selected with a socket height of 3.5-5.0 cm, with 5-7 formed leaves, 2-6 roots and a root system of about 1.5-2.0 cm. Plants were removed from the culture vessels, the roots were washed from agar in distilled water, and then placed in vegetative cassettes with sterile quartz sand with a volume of 50 ml. The control group of plants was moistened with an aqueous solution containing

concentration of standard components of the medium according to the prescription Murashige and Skoog. 5 ml of the working solution was added under each plant by irrigation. The experiments were carried out in duplicate, in each version at least 30 regenerants were used. In order to prevent dehydration, the first 10 days the plants were in a microparic (humidity 80-90%), then they were grown under normal conditions, sprayed with water twice a day. Irrigation with solutions was carried out three times per stage at equal intervals of time, in between the substrate was moistened with distilled water. The duration of this adaptation period was 4 weeks, with a 16-hour photoperiod, a temperature of 23-25 ° C and an illumination of 2-3 klx. Plant survival was fixed when new leaves appeared at the end of the period. Plant survival was understood as the ratio of the number of rooted regenerated plants to the actually planted number, expressed as a percentage. After 4 weeks, the plants were removed from the culture vessels and the following growth parameters were measured: the number of leaves, the number of roots, the height of the rosette, the length of the root system, the growth rate of these indicators for the study period was determined.

At the final stage of adaptation, the plants were extracted from sterile sand and transplanted into glasses with a 150 ml soil substrate consisting of a mixture of peat with perlite, humus and sand in a ratio of 1: 1: 0.5, preventing the top kidney from falling asleep. Adaptation was carried out in a greenhouse at a 16-hour photoperiod, temperature 23-25 ° C, illumination of 15 klx and humidity 60-70%. Planted plants were sprayed and regularly watered.

The results are shown in table 1.

Example 2 (experiment: with a mechanocomposite)

концентрации стандартных компонентов среды по прописи Мурасиге и Скуга, а водной суспензией механокомпозита на основе рисовой шелухи и зеленого чая (концентрация 3 г/л). Суспензию механокомпозита для полива готовили свежую, механокомпозит перемешивали с водой комнатной температуры, настаивали 1 час при комнатной температуре, не фильтровали, при поливе постоянно перемешивали.The inventive method was carried out according to example 1 with the only difference: the plants were moistened with a non-aqueous solution containing

concentrations of standard components of the medium according to the prescription Murashige and Skoog, and an aqueous suspension of a mechanocomposite based on rice husk and green tea (concentration 3 g / l). A suspension of the mechanocomposite for irrigation was prepared fresh, the mechanocomposite was mixed with water at room temperature, insisted for 1 hour at room temperature, not filtered, constantly mixed during irrigation.

The results are shown in table 1.

Notes: ¹ - Treatment with an aqueous solution of 1/4 concentration of the medium according to the prescription Murashige and Skoog.

² - Treatment with an aqueous suspension of a mechanocomposite, 3 g / l.

³ - The presence of significant differences by the U-criterion (at p≤0.05).

⁴ - The average value of the indicator ± standard error of the mean.

The research results showed that after 4 weeks of cultivation of large-fruited strawberries in cassettes when irrigated with an aqueous suspension of a mechanocomposite based on rice husk and green tea, all the studied varieties showed a fairly high survival rate of regenerated plants (99.0-100%) compared with the control variants (86 , 8-100%). When using this drug, an increase in plant survival in the varieties Tsaritsa, Festivalnaya and Smile of June was revealed by 13.2%, 8.3% and 5.9%, respectively (Table 1).

The success of the adaptability of regenerants is largely determined by biometric indicators of plant growth parameters. In the present experiment, the plants were distinguished by a well-formed rosette of leaves in both variants. Moreover, morphometric indicators of the number of leaves of the studied samples, except for the variety “Smile of June”, did not have significantly significant differences. At the same time, the stimulating effect of the mechanocomposite on the growth of the aerial part of regenerated plants was found. The increase in the height of the outlet in almost all the studied varieties treated with an aqueous suspension of a mechanocomposite significantly exceeded the control variant. Depending on the genotype, the height of the outlet increased relative to the control by 1.3–4.1 times, except for the variety “Smile of June”. Perhaps this deviation from the general growth trend of the aerial parts in this variety is due to its genetic characteristics.

The present experiment also showed the positive effect of treatment with an aqueous suspension of a mechanocomposite based on rice husk and green tea on the growth of the root system of regenerated plants (Table 1). Almost all studied varieties treated with an aqueous suspension of the mechanocomposite showed a more intensive root growth compared with the control variants. The length of the root system significantly increased 1.1-2.0 times depending on the genotype. In the Tsaritsa variety, an increase in this indicator turned out to be unreliable, although a tendency to an increase in the length of the root system was also observed. Regenerants of the Borovitskaya, Solnechnaya Polyanka and 5-90-21 hybrid cultivars treated with an aqueous suspension of the mechanocomposite formed a significantly larger number of roots compared to the control variants. The number of roots increased 1.3-1.8 times, respectively, compared with the control group.

For all varieties, a significant increase in biometric indicators was recorded for at least one of the growth parameters of plants (Table 1).

After adaptation in sand, plants were transferred to containers with a substrate consisting of a mixture of peat with perlite, humus and sand (1: 1: 0.5), and after 4 weeks in glasses with the same mixture. The survival rate at this stage was 99.9%. After 6 weeks, the seedlings met the requirements for planting material of large-fruited strawberries with a closed root system (9. National standard of the Russian Federation. GOST R 53135-2008. Planting material of fruit, berry, subtropical, walnut, citrus crops and tea. Technical conditions).

The technical result of the claimed technical solution is to improve the adaptation of large-fruited strawberries, expressed in improving the growth and survival of F. ananassa regenerated plants under ex vitro conditions (up to a level of at least 99%), thanks to the feeding of microplants at the stage of adaptation with an aqueous suspension of a silicon-containing mechanocomposite based rice husk and green tea.

The use of the invention will allow microplants of large-fruited strawberries with the help of a mechanocomposite based on rice husks and green tea to successfully pass the stress phase - the ex vitro adaptation period - and thereby ensure the fast and effective survival of planting material of large-fruited strawberries.

The socially beneficial effect of using the invention is to provide the population with the fruits of large strawberries.

An additional positive effect achieved by the invention is the possibility of developing the chemical industry in line with the ideology of "green" chemistry, which requires a significant increase in the share of renewable raw materials in the chemical industry, and this can be done, in particular, due to new developments in the field of processing renewable plant materials, such as a technology for the production of silicon-containing mechanocomposite based on rice husk and green tea.

Claims (1)

A method of adaptation of strawberry regenerated plants, comprising the adaptation step, characterized in that the regenerated plants of large strawberry during the adaptation period are moistened three times at regular intervals by a freshly prepared aqueous suspension of a silicon-containing mechanocomposite based on rice husk and green tea, prepared by mixing the mechanocomposite and water room temperature at a concentration of 3 g / l and subsequent infusion for 1 hour at room temperature, and in between moisten di Stilled water.