1. Introduction
Synthetic fungicides are commonly applied in conventional agriculture for the control of seed-borne fungi. In the last few decades, however, due to the development of organic farming, various methods of physical seed treatment are acquiring increasing interest. These methods are mainly based on the use of thermal energy in a dry (e.g., elevated temperatures, solar heat) or wet (e.g., hot water, aerated steam) form. However, radiation (e.g., solar, ionizing, microwave) is also being increasingly applied for seed treatment [
1]. Microwaves are ultra-high frequency electromagnetic waves widely used in many areas of human life, such as the agri-food industry, communication, medicine, and metallurgy. Thermal effects of microwave treatment are the best known, although, considering the influence of microwaves on living organisms, some nonthermal effects, leading to various types of molecular transformations and alterations, have been also suggested [
2]. Microwave treatment was efficiently used for the control of several seed-borne fungi, such as
Ascochyta lentis and
Botrytis cinerea in lentil [
3,
4],
Fusarium graminearum in wheat [
5],
Colletotrichum lindemuthianum in bean [
6],
Fusarium spp. and
Microdochium nivale in wheat [
7], and
Alternaria spp. and
Ustilago nuda in barley [
8,
9]. Biological effects of microwaves depend on the field strength and frequency, wave forms, and duration of exposure [
10]. The prolongation of microwave treatment and an increase in the power output and frequency of waves, associated with an increase in temperature, usually results in a deterioration in seed viability [
5,
6,
11,
12,
13,
14,
15,
16]. In contrast, it has been reported that properly applied microwave treatment can significantly improve seed germination and seedling emergence [
10,
15,
16,
17,
18,
19,
20].
Carrot (
Daucus carota L.) is among the most popular and economically important vegetables in the world [
21]. One of the main worldwide problems associated with the production of this crop are diseases caused by seed-transmitted fungi from the genus
Alternaria, i.e.,
A. dauci, which is responsible for leaf blight, and
A. radicina, which is a causal agent of black rot of roots and seedling damping-off [
22].
Alternaria alternata, another fungus from this genus commonly identified on carrot seeds, has been reported by some researchers as a weak pathogen of this plant. The abundant presence of
A. alternata, especially in connection with seed infestation with
A. dauci and/or
A. radicina, may negatively affect seed germination [
23]. The widespread nature of
Alternaria spp. triggers resistance of these fungi to many standard fungicides [
24,
25]. Moreover, the use of pesticides in organic farming is strictly limited. Thermotherapy, based on hot water treatment, has already been proven to be efficient for the control of
A. dauci and
A. radicina on carrot seeds [
26]. Microwave radiation in comparison with a conventional heat treatment is simple, rapid, and easy to control. Soaking seeds in water during their exposure to microwaves makes this procedure more complicated, but may protect the seeds from injuries caused by overheating. Therefore, the aim of the present experiment was to investigate the effects of dry and wet microwave treatments on germination and health of carrot seeds.
2. Materials and Methods
Two commercially available standard carrot seed samples (sample I—cv. Amsterdam, lot No PL 004/63/51/020A and sample II—cv. Berlikumer, lot No PL 104/63/51/233A) obtained from Torseed Seed Company in Toruń were tested. The samples varied in seed quality. Both samples were characterized by a low germination at the final count, 50% and 29% in samples I and II, respectively. All seeds of both samples were infested with Alternaria alternat, but in sample I a higher percentage (38%) of seed infested with pathogenic Alternaria radicina was noted than in sample II (5%). The seeds were treated in a Whirlpool microwave oven type M593 (microwave frequency 2.45 GHz, wave length 12.24 cm).
For each treatment, 1 g of seeds was placed as a single layer in a 9 cm diameter glass Petri dish, or 2 g of seeds was placed in a beaker with a capacity of 100 mL filled with distilled water to a volume of 50 mL. Plates with dry seeds (dry treatment) and beakers with seeds soaked in distilled water (wet treatment) were placed centrally in the microwave oven and treated at three different power output levels—500, 650, and 750 W—for 15, 30, 45, 60, 75, and 90 s. The control for both dry and wet treatments included untreated seeds. Directly after wet treatment, seeds were transferred into a sieve and cooled under tap water for 2 min and then dried for 24 h at 20 °C and 45% RH. In addition, after each wet treatment, the water temperature was measured. The moisture content of dry untreated and dry treated seeds was evaluated using the high-constant-temperature oven method, based on the International Seed Testing Association (ISTA) Rules [
25]. The test was carried out in two replicates of 0.5 g of seeds from each treatment. The seeds were dried at 130 °C for 1 h and the moisture content was calculated based on the difference between seed weight before and after drying.
For untreated and microwave treated seeds, germination and health tests were performed. Seed germination was evaluated on six replicates of 50 seeds from each treatment. Seeds were placed in 9 cm diameter Petri dishes (50 seeds per dish) on six layers of blotter paper moistened with distilled water and then incubated for 14 days at 20 °C in the dark. After 7 and 14 days of incubation, germination at the first and final counts (the percentage of normal seedlings) was evaluated, respectively. Moreover, after 14 days the percentages of abnormal diseased seedlings, abnormal deformed seedlings, and ungerminated fresh and dead seeds were determined according to ISTA Rules [
27].
The deep-freeze-blotter test was applied for seed health analysis [
28,
29]. For each treatment, 200 seeds, i.e., 5 replicates of 40 seeds, were tested. The seeds were placed in 9 cm diameter Petri dishes on six layers of blotter paper moistened with distilled water, 20 seeds per dish. The seeds were incubated in darkness at 20 °C for 3 days, at −20 °C for 24 h, and then for 8 days at 20 °C under 12 h alternating cycles of NUV light and darkness. Then, the fungi were identified on the basis of their growth and sporulation using stereoscopic and compound microscopes [
30,
31]. The percentages of seeds infested with individual fungi and seeds free of fungi were determined.
All parameters describing seed germination and the percentages of seed infestation with individual fungi were evaluated by one-way analysis of variance followed by Duncan’s multiple range test, at a level α = 0.05.
4. Discussion
Thermotherapy is one of the oldest approaches of seed sanitation, but because of numerous practical limitations, it has never been widely used in conventional agriculture for the control of seed-borne fungi. The development of organic farming renewed interest in physical seed treatment methods, such as thermotherapy, including the use of hot water, hot humid air, and microwave radiation. Hot humid air (ThermoSeed technology) has been used routinely in Sweden and Norway for many years to control seed-borne pathogens in cereals [
32,
33]. Microwave technology offers several advantages, including safety, high efficiency, and environmental protection.
The results of the performed experiment showed that wet treatment, i.e., soaking seeds in water during their exposure to microwave radiation, was generally much more effective in controlling the incidence of
Alternaria alternata, A. dauci, and
A. radicina on carrot seeds in both examined samples than dry treatment. Basically, the dry treatment did not affect the level of seed infestation with
A. alternata and
A. dauci. Only in the case of sample I seeds, which were infested with
A. radicina to a much higher degree than sample II seeds, some reduction in the incidence of this fungus was found after treating dry seeds with microwave radiation, mainly at power output levels of 650 and 750 W. The moisture content of untreated seeds in sample I was 8.3% and in sample II was 9.6%. Tylkowska et al. [
18] reported that treating dry (9.5% m.c.) common bean seeds with microwaves in a microwave oven with a power output of 650 W and frequency of 2450 MHz for 15–120 s did not control
A. alternata and
Fusarium spp., but diminished the presence of
Penicillium spp. It has been suggested that dark, multi-celled, and thick-walled spores, in addition to dark mycelium (e.g.,
Alternaria spp.,
Bipolaris sp.), are less sensitive to microwave radiation than hyaline and one-celled spores (e.g.,
Aspergillus spp.,
Penicillium spp.) [
18,
34]. The study of Mangwende et al. [
35] showed that higher seed moisture content translates to an increase in efficacy of microwave radiation against seed-borne fungi. Water molecules are polar; they rotate when exposed to microwaves and the rotation produces heat. Dried samples are not affected due to the lack of polar molecules, whereas those in the presence of water can reach lethal temperatures [
36].
The mechanism of microbial inhibition caused by microwave radiation is based on the internal heating of the seeds resulting from molecular movement in the pulsing electromagnetic field. This leads to the denaturation of proteins, enzymes, and nucleic acids. Proteins are directly damaged by heating as the bonds holding them together are destroyed. However, this also implies the risk of losing enzymatic activities, which are essential for carrying out metabolic processes [
36,
37,
38]. It has been reported, based on the study performed on
A. parasiticus, that the severity of DNA injury increased with rising temperatures [
37]. Moreover, non-thermal microwave effects in terms of energy required to produce various types of molecular transformation and alterations have been reported [
2]. Electroporation is one of the non-thermal effects caused by microwave radiation. Microwaves at sub-lethal temperatures induce the formation of pores in a cellular membrane due to their interaction with polar molecules. These pores allow the cellular contents, including DNA, to leak outside [
36]. It has been found that the lethal effect of low-dose microwave radiation (LDMR) on spoilage microorganisms was a result of a disruption of the cell membrane and induced DNA damage [
37]. Based on studies concerning the effect of microwave radiation on the death rates of
Escherichia coli, it has been proposed that microwaves either cause ions to accelerate and collide with other molecules, or cause dipoles to rotate and line up rapidly (2450 million times/s) with an alternating electric field, resulting in a change in the secondary and tertiary structure of proteins of microorganisms [
2]. Knox et al. [
7], who observed that the number of viable fungal propagules on wheat seeds decreased after microwave treatment, but the level of fungal DNA remained unchanged, concluded that the death of fungi was connected with high temperature and desiccation rather than DNA denaturation. Microwaves cause various biological effects depending upon field strength, frequencies, wave forms, modulation, and duration of exposure [
2].
In this study, exposure of dry seeds to microwave radiation generally did not influence their germination or showed adverse effects. An improvement in seed germination at the first and final counts was observed only in sample I, characterized by higher initial seed germination than in sample II, after the use of microwave radiation at power output of 500 W for 45 and 75 s, and 650 W for 75 s. It should be also emphasized that seed germination at the first count is an indicator of seed vigor, because it shows the percentage of normal seedlings that developed in a short time. It has been found that seed moisture content decreased with the increase in the power output and treatment duration. Aladjadjiyan [
13] presented the hypothesis that greater energy absorbed by molecules at a higher power output level and longer exposure time may have a deleterious effect on cell functions. The study of Knox et al. [
7] revealed that deterioration of wheat seeds’ viability as a result of microwave treatment was undeniably linked with a decrease in seed moisture content. Bhaskara Reddy et al. [
5] found that germination and vigor of microwave treated wheat seeds was reduced significantly at 8% m.c. According to the authors at this moisture content, the free water was lost sooner than at higher moisture contents (14% and 20%), leaving only the bound water in the seed to absorb energy. During the treatment, progressively lower amounts of microwave power were absorbed by the free water relative to those absorbed by the lipids and proteins of the seeds. At higher moisture content, most of the power is absorbed by the free water in the seed, thus resulting in less damage. Mangwende et al. [
35] observed that microwave radiation of moist
Eucalyptus seeds increased their germination to a larger extent than in the case of dry seeds. Aladjadjiyan [
39] also reported that a preliminary soaking of common bean seeds in distilled water increased the effect of microwave stimulation by more than 25%.
It can be supposed that soaking seeds in water might affect their infestation with fungi by removing a superficial inoculum. Our previous experiments showed that soaking carrot seeds in water for a short period of time (15–120 s) did not reduce seed contamination with fungi; on the contrary, the increase in the incidence of some of them was observed (personal observation). However, some fungal propagules present on the seed surface could be removed during rinsing the seeds under tap water after wet microwave treatment.
It was found in the present study that the exposure of seeds soaked in water to microwave radiation, especially for 45–90 s, irrespective of the applied power output level, resulted in a significant decrease in seed infestation with
Alternaria spp. Moreover, after the wet treatment, high percentages of seeds free of fungi were noted, whereas in the control they were not observed. It is likely that most fungi present on seeds, not only
Alternaria species, were eradicated by this treatment. From the difference in the efficacy of dry and wet treatments, it may be concluded that
Alternaria spp. mostly contaminated seeds. Some researchers reported previously that
Alternaria spp. inoculum is located mainly on the carrot seed surface [
25,
40,
41]. Wet treatment combines the internal heating of seeds caused by microwave radiation with hot water treatment, which mainly affects the fungal inoculum present on the seed surface or located in a few internal layers of a seed. Microwave radiation can rapidly penetrate seeds at the cellular level, killing seed-borne pathogens deeply imbedded in seed tissues. Strandberg and White [
42] reported that soaking carrot seeds in hot water at 50 ℃ for 20 min decreased their infestation with
A. dauci, whereas Pryor et al. [
43] found that hot water treatment at 50 ℃ for 30 min eliminated
A. radicina. Hermansen et al. [
44] reported that hot water treatment of carrot seeds at 44, 49 and 54 ℃ generally improved germination of infected seeds and reduced the incidence of
A. dauci. The treatment at 54 ℃ for 20 min eradicated this fungus without adversely affecting seed germination, seedling emergence, and yield. According to Nega et al. [
26], hot water treatments at 50 ℃ for 30 min and at 53 ℃ for 10 min reduced the incidence of fungi from genus
Alternaria on carrot seeds by 85% to 98%. In our study, the exposure of seeds soaked in water to microwave radiation for 45–120 s, irrespective of the power output level, resulted in a significant decrease in seed infestation with
A. alternata, A. dauci, and
A. radicina, and in the increase in the percentage of seeds free of fungi in both samples. The average temperature of water after these treatments, depending on the power output and treatment duration, ranged from 48.0 to 92.0 ℃. It rose with the increase in the power output level. Unfortunately, the exposure time exceeding 60 s generally had an adverse effect on seed germination, especially at the microwave power output of 650 and 750 W. A significant decrease in seed germination combined with the increase in the percentage of abnormal deformed seedlings was observed in both samples, if water temperature during wet treatment exceeded 80 °C. In sample I, characterized by the higher initial seed vigor and germination, and the much greater infestation with pathogenic
A. radicina than in sample II, an enhancement of germination at the first and final count was observed in most cases. This was likely caused by the decreased incidence of the pathogen. The most significant improvement in seed germination at the final count was observed when seeds soaked in water were exposed to microwave radiation at 500 W for 75 s, at 650 W for 45 s, and at 750 W for 60 s. The water temperature in these treatments reached 66, 58, and 67 ℃, respectively. In sample II, an increase in seed germination was noted after wet treatment at the power output of 500 W for 60 and 90 s (water temperature 62.5 and 74.5 ℃, respectively), and 650 W for 60 s (63.5 ℃). The water temperature in these treatments was higher than the temperature recommended for hot water treatments mentioned above, but the duration was much shorter. In some cases, the influence of treatment duration on seed germination seems to be inconsistent. Some variation in water temperature between replications for each treatment variants was observed. This was probably caused by the lack of homogeneity of the field distribution in the microwave oven. In the oven, microwaves resonate in the cavity and form standing waves, but the nodes and antinodes of these waves can cause the product to burn in some places but to remain cool in others [
45]. Therefore, further experiments are necessary to eliminate this problem during microwave seed treatment.