- Detalles de la revista
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- Revista
- eISSN
- 2353-3978
- Primera edición
- 30 Jul 2013
- Calendario de la edición
- 2 veces al año
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Rose hips are a rich source of bioactive compounds with potential beneficial effects on human health. There is growing demand for good quality and uniform planting materials for establishing rose hip plantation. The low rooting ability of stem cuttings of many selected genotypes of hip roses and heterogeneousness of generative planting material are the limiting factors for rapid implementation of rose hip in horticultural production.
There is great variation in the rooting capacity of cuttings of fruit-producing rose genotypes. Depending on the time of harvesting the cuttings and the type and concentration of phytohormones used, the percentage of cutting rooting varies from 10% to 86% for selected
Light is an important factor for modulating root development, and providing optimal light conditions can greatly improve the success of propagation. Light-emitting diodes (LEDs) have many potential benefits for propagation. The narrow emission spectra of LEDs allow to design a lighting system capable of stimulating specific photoreceptors (Davis & Burns 2016). Using spectral manipulation to improve propagation efficiency is of particular interest for high-value crops that are difficult to root. Many scientific reports concern the impact of light quality on plant reproduction using micropropagation techniques (Miler et al. 2019), and little work is related to ornamental plant propagation by softwood cuttings (Christiaens et al. 2016). It has been demonstrated that limiting the spectrum to 100% red light is not always optimal for propagation, but a range of red to blue light mixtures have been found to produce optimal rooting conditions for several species (Christiaens et al. 2016, Davis & Burns 2016). However, there is not much information available on the potential benefits of LED lighting for rooting cuttings of woody plants, including
Vertical farming is the production of plants in multiple vertical layers indoors with a controlled environment and LEDs as the only light source (Kozai et al. 2020). In the past few years, there has been a worldwide increase of interest in vertical farming, especially to produce high-value specialty crops including leafy greens, herbs, and pharmaceutical crops. Indoor vertical production may also have many potential benefits for growing crops that are difficult to propagate in less-controlled greenhouse environments.
The aim of the study was to assess the impact of light quality generated by LEDs on adventitious root formation and cuttings’ quality of
Two-node softwood cuttings, 4–5 cm long, of
The experiment was conducted in a 15-m2 walk-in growth chamber equipped with three levels of shelves on both sides with white LED tubes (6500 K) mounted above the shelves. Four different light treatments (16/8-h light/dark photoperiod) were applied during the rooting period as follows: 1) white LED tubes at 50 μmol·m−2·s−1 (control), 2) white LED tubes at 100 μmol·m−2·s−1, 3) red LEDs at 50 μmol·m−2·s−1 + white LED tubes at 50 μmol·m−2·s−1, and 4) blue LEDs at 50 μmol·m−2·s−1 + white LED tubes at 50 μmol·m−2·s−1. Slim panels (130 cm in length) of custom-built LED arrays containing red (660 nm) or blue (440 nm) LEDs (OSRAM, Germany) were arranged between white LED tubes to ensure adequate light quality for treatments 3 and 4. To obtain an adequate photosynthetic photon flux density (PPFD) value, various numbers of white LED tubes (three or five) were used per shelf, and also the distance between the light source and the shelves was adjusted. PPFD was measured in the middle part of empty shelves without plants, separately for white LED tubes and red or blue LED lights. PPFD was measured using a LI-COR quantum photometer Model LI-189. The spectrum of light emitted by white LED tubes, white LED tubes + red LEDs, and white LED tubes + blue LEDs is shown in Figure 1. The emission spectra were measured with LI-180 spectrometer (LI-COR). The shelves with different light treatments were separated with white, lightproof screens. The daily light integrals (DLIs) were 2.88 mol·m−2·d−1 for control and 5.76 mol·m−2·d−1 for other treatments. Temperature in the growth chamber was automatically regulated at 21 °C. Four boxes with cuttings were placed per shelf (60 × 130 cm). Cuttings were prepared on July 19, 2018 and evaluated after 5 weeks (23 August). One hundred and twenty cuttings per treatment (four boxes) were subjected to each light treatment.
Fig. 1
Spectra of different light treatments used in the study: white LED tubes (left), white LED tubes + red LEDs (middle), and white LED tubes + blue LEDs (right), absolute spectrum (W m−2/nm)
The second part of the study was carried out in a greenhouse chamber (5 × 4 m) equipped with four ebb and flow benches. Four different light treatments were applied during the rooting period (i.e. – from 17 September to 22 October 2019) as follows: 1) control, natural light; 2) natural light supplemented with white LEDs; 3) natural light supplemented with red LEDs; and 4) natural light supplemented with blue LEDs. The natural photoperiod throughout the experimental time was on average 11.5 h (initially 12.5 h and at the end of experiment 10.5 h), and the average DLI inside the greenhouse was 5.18 mol·m−2·s−1. Slim, 120-cm long, custom-built LED arrays containing red (660 nm) or blue (440 nm) diodes, such as in the first experiment, and white LEDs (cool-white 5000 K, OSRAM, Germany) were mounted above the benches. Four panels were used above each bench. LED lighting was used as a supplementary to greenhouse light when dusk began (6 p.m. to 10 p.m.) at PPFD 120 μmol·m−2·s−1 at the plant level; thus, DLI inside the greenhouse was increased by 1.73 mol·m−2·d−1. Four boxes of 30 cuttings were placed under each light treatment. Daily maximum/minimum temperature was 21 °C ± 3 °C/18 °C ± 3 °C.
The experiment design included four light treatments with four replications for both experiments. One box consisting of 30 cuttings was treated as one replication. Treatments were analyzed by one-way analysis of variance (ANOVA); means were compared using Tukey's tests at p = 0.05. The data concerning the percentage of rooted cuttings were formerly transformed according to Bliss’ function.
Percentage of rooted cuttings of
Rooting and initial growth of shoots on two-node cuttings of
| LED light treatment PPFD (μmol·m−2·s−1) | Rooting (%) | Number of roots per cutting | Root length (mm) | Fresh weight of roots (mg) | Cuttings with new shoots (%) | Shoot length (mm) | Fresh weight of shoot (mg) |
|---|---|---|---|---|---|---|---|
| White 50 – control | 83.3±3.6 a | 3.3±0.41 a | 50±0.7 a | 79.3±17.1 a | 26.7±3.6 a | 15.7±3.7 a | 274±22 a |
| White 100 | 93.3±2.4 a | 3.9±0.57 a | 51±3.4 a | 89.6±15.7 a | 43.3± 7.2 a | 25.3±3.0 b | 368±44 ab |
| White 50 + Red 50 | 89.7±0.8 a | 3.2±0.48 a | 48±4.7 a | 183.0±27.9 b | 66.7±3.6 b | 23.2±2.6 b | 486±21 b |
| White 50 + Blue 50 | 86.7±1.9 a | 2.7±0.34 a | 44±4.2 a | 124.5±27.4 ab | 39.2±6.6 a | 22.2±2.8 b | 354±25 ab |
Means followed by the same letter do not differ significantly at ≤ 0.05 according to Tukey's test; means ± SE
Rooting and initial growth of shoots on two-node cuttings of
| LED light treatment PPFD (μmol·m−2·s−1) | Rooting (%) | Number of roots per cutting | Root length (mm) | Fresh weight of roots (mg) | Cuttings with new shoots (%) | Shoot length (mm) | Fresh weight of shoot (mg) |
|---|---|---|---|---|---|---|---|
| Natural – control | 61.7±3.2 a | 3.6±0.35 a | 55±3.8 a | 51.9±5.8 a | 21.7±2.1 a | 5.8±0.8 a | 86±12 a |
| White 120 | 67.5±2.8 a | 5.0±0.45 a | 67±5.0 a | 63.3±9.6 ab | 38.3±6.2 a | 7.4±1.1 a | 120±13 a |
| Red 120 | 61.7±6.1 a | 4.9±0.45 a | 72±5.0 a | 88.7±12.2 b | 63.4±4.5 b | 8.4±1.4 a | 100±12 a |
| Blue 120 | 65.0±4.0 a | 4.3±0.45 a | 65±6.1 a | 72.3±8.3 ab | 30.0±5.3 a | 5.6±0.7 a | 118±22 a |
Note: See table 1
Auxins play a pivotal role in adventitious roots formation. Light has been reported to regulate the endogenous level of auxins and their homeostasis and transport through the plant tissues (Halliday et al. 2009, Pacurar et al. 2014). Red light has been shown to be beneficial in promoting root development in several species propagated
In the current study, red light strongly promoted axillary bud outgrowth of
Too high light intensity at the initial stage of rooting may intensify leaf water deficit resulting from increased transpiration and decrease the effectiveness of the rooting process. Such a reaction was not observed in our study under an increase in PPFD from 50 to 100 μmol·m−2·s−1, irrespective of the light spectrum generated by LEDs. Moreover, the length of new shoots of
It is worthwhile to underline that the growth chamber equipped with LEDs as the sole source of lighting created more favorable conditions for the growth and development of cuttings of
The present study has demonstrated the ability to improve the quality of rooted cuttings of
Fig. 1
Rooting and initial growth of shoots on two-node cuttings of Rosa ‘Konstancin’ in response to the quality of LED light and the intensity of irradiation in the growth chamber
| LED light treatment PPFD (μmol·m−2·s−1) | Rooting (%) | Number of roots per cutting | Root length (mm) | Fresh weight of roots (mg) | Cuttings with new shoots (%) | Shoot length (mm) | Fresh weight of shoot (mg) |
|---|---|---|---|---|---|---|---|
| White 50 – control | 83.3±3.6 a | 3.3±0.41 a | 50±0.7 a | 79.3±17.1 a | 26.7±3.6 a | 15.7±3.7 a | 274±22 a |
| White 100 | 93.3±2.4 a | 3.9±0.57 a | 51±3.4 a | 89.6±15.7 a | 43.3± 7.2 a | 25.3±3.0 b | 368±44 ab |
| White 50 + Red 50 | 89.7±0.8 a | 3.2±0.48 a | 48±4.7 a | 183.0±27.9 b | 66.7±3.6 b | 23.2±2.6 b | 486±21 b |
| White 50 + Blue 50 | 86.7±1.9 a | 2.7±0.34 a | 44±4.2 a | 124.5±27.4 ab | 39.2±6.6 a | 22.2±2.8 b | 354±25 ab |
Rooting and initial growth of shoots on two-node cuttings of Rosa ‘Konstancin’ in response to the quality of LED additional lighting in the greenhouse
| LED light treatment PPFD (μmol·m−2·s−1) | Rooting (%) | Number of roots per cutting | Root length (mm) | Fresh weight of roots (mg) | Cuttings with new shoots (%) | Shoot length (mm) | Fresh weight of shoot (mg) |
|---|---|---|---|---|---|---|---|
| Natural – control | 61.7±3.2 a | 3.6±0.35 a | 55±3.8 a | 51.9±5.8 a | 21.7±2.1 a | 5.8±0.8 a | 86±12 a |
| White 120 | 67.5±2.8 a | 5.0±0.45 a | 67±5.0 a | 63.3±9.6 ab | 38.3±6.2 a | 7.4±1.1 a | 120±13 a |
| Red 120 | 61.7±6.1 a | 4.9±0.45 a | 72±5.0 a | 88.7±12.2 b | 63.4±4.5 b | 8.4±1.4 a | 100±12 a |
| Blue 120 | 65.0±4.0 a | 4.3±0.45 a | 65±6.1 a | 72.3±8.3 ab | 30.0±5.3 a | 5.6±0.7 a | 118±22 a |