RU2283561C1 - Method for treating of potato planting material - Google Patents

Abstract

FIELD: agriculture, in particular, plant growing, may be used in elite potato seed growing at different stages of producing sanitated seeds by apical meristem method.

SUBSTANCE: method involves exposing potato planting material to optical radiation flow in red spectrum by means of coherent light at radiation intensity ratio of at least 5:1 within wavelength range of 550-680 nanometer and above 680 nanometer, respectively, at radiation dose of 100-200 J/m². Test plants and potato seed tubers are used as planting material. When potato test plants are used as planting material, irradiation procedures are carried out repeatedly during vegetation phase at least three times, beginning from 5-7 days after procedure of propagation by cuttings, at one day interval. Potato seed tubers are treated 1-3 days before planting thereof. Method allows multiplication pattern of elite potato seeds to be reduced by 1 year.

EFFECT: increased coefficient of multiplication of planting material, increased potato tuber yield, increased efficiency, simplified method and reduced cost of effectuating said method.

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Description

The invention relates to agriculture, in particular to plant growing, and in particular to methods of pre-planting processing of planting material of potatoes, and can be used in elite seed production of potatoes at various stages of the production of healthy seeds using the apical meristem method.

It is known that light is a factor in a powerful effect on the growth and development of plants. The physiological processes in a plant are triggered by light through a photoreceptor system called phytochrome, which converts the energy of light pulses into the energy of biochemical reactions. [Kulaeva O.N. How light regulates plant life. / Sorov educational journal, T.7, No. 4. 2001. - P.6-11].

It is known that phytochrome consists of two mutually transforming forms - PF _to and PF _dc . One form of phytochrome - PF _to absorbs red light and turns into another form - PF _dc . The reverse transformation occurs under the action of the far red light. FC _{physiologically} inactive. Reactions controlled by phytochrome depend on the concentration of PF _dc :

Thus, physiological reactions leading to accelerated growth and development of plants depend on the rate of conversion of PF _to PF _dc and on the content in the plant of the active form of the phytochrome PF _dc [Libbert E. Plant Physiology. - M., Mir, 1976, p. 382-387].

A known method of pre-planting treatment of tubers of seed potatoes, including exposure to tubers with a stream of optical radiation in the spectral range of 360-700 nm, carried out sequentially in 4 stages with a change in the spectral composition and radiation power [see RF patent No. 2076553, IPC A 01 C 1/00, 1997].

The disadvantage of this method is the use at the final stage of processing radiation with a low content of red light in the range of 600-700 nm compared with radiation in the region of 380-500 nm (25-31% and 58-62%, respectively). In addition, the need to use 4 types of sources with a varying spectral composition in this method significantly increases material costs and makes it difficult to integrate an irradiation installation into an existing production line for the propagation of test tube potato plants.

The closest way to the claimed invention in terms of features is a method of pre-sowing seed treatment, including the combined continuous exposure of seeds to red (CS) and infrared (IR) radiation [see RF patent No. 95112900, IPC 01 C 1/00, 1997; RF patent No. 2090031, IPC A 01 C 1/00, 199], adopted as a prototype. IR exposure is carried out with a wavelength of 900 to 980 nm (with a maximum radiation of 940 nm) with a dose rate of 1.0 to 10 W / m ² , exposure to CS with a wavelength of 600-720 nm (with a maximum of 660-670 nm) at a ratio flow rates of doses of CS and IR, respectively, 5: 1-10: 1 s for 60-360 s.

A significant drawback of this method is that it does not take into account the existence of two mutually _transforming forms of phytochrome FC _k and FC _dc noted in the plant, and the authors argue their scheme by referring only to the absorption spectrum of FC _k . The presence in the light flux of radiation with wavelengths above 680 nm leads to a decrease in the content of the active form of phytochrome in the biological system and suppresses the effect of physiological stimulation. In this regard, in the known method of pre-sowing seed treatment, high doses of CS exposure are used. The presence in the luminous flux of physiologically inactive radiation of 900-980 nm, not included in the absorption region of phytochrome, is also a disadvantage of the known method, because does not cause a physiological effect of stimulation of plant growth. Used in the known method, the irradiation scheme is not effective, because does not provide spatial uniformity of the light flux. In addition, the process of seed treatment according to the known method requires significant costs due to the implementation of sources of IR and KS radiation in the form of LEDs based on a solid solution of gallium-aluminum-arsenic or in the form of diode lasers, which does not allow using the known method for processing test tubes and potato seed tubers.

The problem to which the invention is directed is to study the effectiveness of the influence of an optical flux of incoherent red light on plant reactions controlled through the phytochrome system: seed germination, formation of leaf buds, shoot growth, tuberization.

The technical result from the use of the invention is to increase the reproduction rate of planting material, increase the yield of tubers and reduce the reproduction scheme of elite potato seeds by 1 year, as well as to increase efficiency, simplify and reduce the cost.

The specified technical result is achieved by the fact that in the method of processing planting material of potatoes, including exposure to a stream of optical radiation in the red region of the spectrum, the effect is carried out by incoherent light with a radiation power ratio of at least 5: 1 in the wavelength range of 550-680 nm and more than 680 nm, respectively with a radiation dose of 100-200 J / m ² .

It is advisable when used as planting material of test tube potato plants to produce exposure during the growing season.

Preferably, when potato tubers are used as planting material, exposure should be made no later than 1-3 days before planting.

It is advisable that exposure to test tube potato plants with incoherent light begin 5-7 days after the cuttings.

Preferably, exposure to test plants with incoherent light is carried out repeatedly during the growing season, at least three times, with an interval of one day.

Figure 1 shows the design of a device for implementing the method of processing planting material of potatoes. Figure 2 shows a histogram of the differential spectrum (PF _to minus PF _dc ), showing the interconversion of two forms of phytochrome depending on the wavelength of the incident flux (1), as well as a histogram of the distribution of radiation intensity depending on the wavelength of the incident flux for an incoherent source (2 ) From figure 2 it is seen that the ranges of the most common radiation intensities of an incoherent source practically coincide with the region of maximum accumulation in the biological system of the active form of phytochrome FC _dc .

A device for implementing a method for processing planting material of potatoes includes an extended gas discharge lamp 1 with a filling that provides a radiation power ratio of at least 5: 1 in the wavelength range of 550-680 nm and more than 680 nm, respectively. Lamp 1 is placed in a system of reflectors 3 and mounted on a rack where tube plants are propagated (together with a mercury fluorescent lamp used in existing technology for additional illumination of tubes at night). Test plants 2 are mounted in racks parallel to the discharge lamp 1 at a distance of not more than 7 cm from the axis of the lamp, which provides a power density of red light emission of at least 0.1 mW / cm ² . The processing time is determined by the above dose.

When potato seed tubers are used as planting material, tubers are placed in place of the tubes, which are placed on the shelf along the lamp in one row at a distance of no more than 7 cm from the axis of the lamp. The irradiation technique and treatment dose are similar to test plants.

Examples of the method

Example 1

Test tube plants of Sante potato were irradiated with incoherent light at two doses of 100 and 200 J / m ² . For this, test tube racks were mounted in a row parallel to an extended gas discharge lamp with radiation in the above range at a distance of no more than 7 cm from the lamp axis. The treatment time was determined by the radiation dose indicated above and was 15 and 30 min, respectively. The irradiation is three times, the first - on the fifth day after the cuttings, the next - with an interval every other day. The control was unirradiated plants. The control and experimental options included twenty-five plants in four repetitions.

According to the existing technology for the propagation of virus-free potato planting stock, the growth of the cut plant in vitro occurs within 3-5 weeks, depending on their achievement of the desired height and the number of internodes over which the cuttings occur. The greater the height of the plant and the number of internodes, the higher the reproduction rate of the test plants will be, thereby reducing the time to obtain the right amount of planting material.

During the growing season, the height of the experimental and control plants was measured; measurements were taken at intervals of 5–7 days. At the end of the growing season (21 days after the cuttings), in addition to measuring the height, the number of internodes was calculated.

Next, control and experimental test plants were planted in the greenhouse and observed their growth and development. At the time of harvesting the greenhouse tubers, the survival of plants was determined (the percentage of surviving plants in relation to the number of plants planted) and the mass of tubers from one bush.

RESULTS.

The average values of the test results are presented in tables 1 and 2.

As follows from the test results shown in table 1, in irradiated plants at the end of the growing season, the height of the plants steadily increases by 6.1-7.8% and the number of internodes by 10-12.1% compared with unirradiated, which leads to an increase the multiplication factor of test plants 1.1-1.3 times. When planting irradiated test plants in a greenhouse, their survival is improved by 14-19% and the yield from one bush is increased by 13.1-22.1% (Table 2). Due to this, the time for obtaining the right amount of planting material is reduced.

Example 2

Potato seed tubers of super reproducible reproduction of varieties Sante and Lugovskaya were irradiated with incoherent light at an irradiation dose of 100 J / m ² (treatment time 15 min). For this, seed tubers were placed on a rack in a row in parallel with an extended gas discharge lamp with radiation in the above range at a distance of no more than 7 cm from the lamp axis.

Irradiated tubers were planted in the field on the third day after treatment simultaneously with control non-irradiated tubers. Landing was carried out with four-row plots of 100 pieces per plot in accordance with a 70 × 30 pattern in four repetitions. Thus, the area of one experimental plot was 15.75 m ² .

In the experiment, phenological observations were carried out in the main phases of the growth and development of potato plants according to the methodology of the All-Russian Scientific Research Institute of Agricultural Sciences (1967). Tuber yield was determined by continuous harvesting with weighing, followed by conversion to hectare. The structure of the crop was determined immediately before harvesting, for which the number and weight of tubers from 10 plants were taken into account in the following fractions: small - less than 40 g, seed - 40-80 g, food - more than 80 g (according to the methodology of VNIIKH, 1967). The solids content in the tubers was determined by drying at 105 ° C to constant weight.

RESULTS

The positive effect of incoherent red light during preplant planting of seed tubers on growth dynamics, yield formation and potato quality was revealed. From the first phases of development, a noticeable advance in growth was noted in comparison with the control of experimental plants. It was found that this method of processing planting material of potatoes, stimulating the initial growth processes in plants, increases the size of the assimilation surface of the leaf apparatus and the productivity of photosynthesis. Ultimately, this determined the level of yield of potato tubers. When using this method of processing planting material, the productivity of tubers of both varieties is increased by 22.4-34.2%, including by fractions of seed and ware potatoes - by 23.7-50.8% (Table 3). The tuber multiplication coefficient for seed and ware potato fractions increases 1.1-1.3 times.

Under the influence of light from an incoherent source in the above range, not only the productivity of plants increases, but also, which is no less important, the quality of tubers. The content of dry matter in tubers increased by 1.4-4.3% (Table 3).

Thus, studies conducted to study the effect of the flow of optical radiation incoherent red light on planting material of potatoes convincingly showed the effectiveness of this method. We revealed a positive effect of incoherent red light on the growth dynamics of test and field potato plants, the formation of yield and quality of tubers. When using this method of processing test-tube plants and seed potato tubers, the multiplication factor of planting material increases, the yield of tubers increases, and the elite potato seed propagation pattern is reduced by 1 year.

The method of processing planting material of potatoes

Table 1
The height of the test plants and the number of internodes at the end of the growing season Indicators The control Exposure to COP 15 min Deviation from the control,% Exposure to COP 30 min Deviation from the control,% Plant height, mm 59.2 ± 3.3 63.8 ± 3.5 7.8 62.8 ± 2.7 6.1 The number of internodes 4.80 ± 0.46 5.38 ± 0.51 12.1 5.28 ± 0.47 10.0 table 2
Survival and productivity of greenhouse plants Indicators The control Exposure to COP 15 min Deviation from the control,% Exposure to COP 30 min Deviation from the control,% Survival rate,% 73 87 fourteen 92 19 The mass of tubers from one bush, g 55.1 ± 5.7 62.3 ± 4.9 13.1 67.3 ± 6.8 22.1 Table 3
Productivity and quality of field reproduction tubers Indicators Variety Sante Grade Lugovskoy The control Exposure to COP 15 min Deviation from the control,% The control Exposure to COP 15 min Deviation from the control,% Productivity, t / ha total 15,5 20.8 34.2 21,4 26.2 22.4 including by fractions of seed and ware potatoes 11.8 17.8 50.8 19.8 24.5 23.7 The content in the tubers of dry matter,% 25.1 26.5 1.4 23.1 27.4 4.3

Claims (8)

1. A method of processing planting material of potatoes, including exposure to a stream of optical radiation in the red spectral region, characterized in that the exposure is carried out with incoherent light with a radiation power ratio of at least 5: 1 in the wavelength range of 550-680 nm and more than 680 nm, respectively, with a radiation dose of 100-200 J / m ² . 2. The method according to claim 1, characterized in that test tubes are used as potato planting material. 3. The method according to claim 1, characterized in that the seed potatoes are used as potato planting material. 4. The method of processing planting material according to claim 2, characterized in that the effect is carried out by incoherent light during the growing season. 5. The method of processing planting material according to claim 4, characterized in that the exposure is carried out with incoherent light 5-7 days after the cuttings. 6. The method of processing planting material according to claim 4, characterized in that the impact is carried out repeatedly, at least three times. 7. The method of processing planting material according to claim 6, characterized in that multiple exposure is performed at intervals of one day. 8. The method of processing planting material according to claim 3, characterized in that seed potato tubers are used as planting material, the effect is carried out by incoherent light no later than 1-3 days before planting.

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