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ISSN : 1225-5009(Print)
ISSN : 2287-772X(Online)
Flower Research Journal Vol.32 No.3 pp.120-131
DOI : https://doi.org/10.11623/frj.2024.32.3.02

Growth and Photosynthetic Responses of Schlumbergera truncata ‘Red Candle’ under Elevated Night-time CO2

Seo Hee Jung, Seo Youn Lee, Jae Suk Lee, Yoon Jin Kim*
1Department of Horticulture, Biotechnology and Landscape Architecture, Seoul Women’s University, Nowon-gu, 01797 Seoul, Korea


Correspondence to Yoon Jin Kim Tel: +82-2-970-5614 E-mail: yj1082@swu.ac.kr ORCID: https://orcid.org/0000-0003-2260-1563
12/07/2024 13/08/2024

Abstract


Schlumbergera truncata absorbs CO2 through its mature phylloclades during the night, and can use a substantial amount of CO2 without requiring ventilation. This study investigated the growth and photosynthetic responses of S. truncata ‘Red Candle’ at two CO2 levels—ambient (≈ 400 μmol・mol-1) and elevated (≈ 1000 μmol・mol-1). At 0–8 weeks after treatment (WAT), width and length of mature phylloclade and length of immature phylloclade did not differ significantly among the CO2 treatments. At 4–8 WAT, number of branches and phylloclades were significantly greater in plants grown under ambient CO2 than those under elevated CO2. Net CO2 uptake was highest in mature phylloclades of plants grown under ambient and elevated CO2 regimes at night, at 2.51 and 1.30 μmol·CO2·m-2·s-1, respectively. However, no statistically significant variation was observed at 6 WAT, and stomatal conductance was significantly affected only by CO2 uptake time at 6 and 8 WAT. Water-use efficiency of mature and immature phylloclades at night increased with increase in CO2 levels (r = 0.7462 and 0.9312, respectively). At 123 days after treatment, plants grown under elevated CO2 had 82.7 floral buds, compared to 72.1 buds in those under ambient CO2. However, this difference was not statistically significant. Moreover, S. truncata grown under elevated CO2 exhibited decreased growth and photosynthesis, whereas the number of floral buds did not exhibit any significant differences among the treatments.



cactus , christmas cactus , CO2 enrichment , crassulacean acid metabolism , photosynthesis

초록

    Introduction

    Greenhouse systems manipulate the growth environment to enhance plant production and flowering quality (Proietti et al. 2022). However, heating and cooling in greenhouses often generate a large amount of surplus CO2 (Cho et al. 2022). Developed in Korea, rooftop greenhouses are installed on empty spaces on building rooftops to reduce the building’s energy load and decrease the energy consumption (cooling/heating/CO2) required for crop production (KIMM 2019). Moreover, rooftop greenhouses utilize building energy for stable cultivation regardless of climate change and take advantage of discarded energy in the city, thus reducing cultivation energy (Kim et al. 2019). The surplus CO2 can be used in the production of ornamental plants in greenhouses by a high-efficiency distributed power generation system (Lee et al. 2015). Plants are divided into C3, C4, and Crassulacean acid metabolism (CAM) types based on their photosynthetic processes (Drennan and Nobel 2000). CAM plants use surplus CO2 generated by cooling and heating at night when ventilation is not needed in a greenhouse.

    Schlumbergera truncata is a multi-flowering cactus that exhibits a variety of flower colors and splendid flowers, and it is a popular ornamental plant in Europe, America, and Korea (Lee et al. 2020). S. truncata grows in phylloclade units and it takes 30 to 60 days for a phylloclade to develop (GARES 2020). S. truncata is a short-day plant with flowers blooming at the apical end of 3 to 5 phylloclades (Lee et al. 2020). Cactus and succulents are known to be representative CAM plants (Cushman and Bohnert 1999). However, research on cactus photosynthetic characteristics is insufficient due to their morphological characteristics (Lee et al. 2003), and studies are mainly conducted on edible cactus such as Opuntia ficus-indica and Hylocereus undatus. Therefore, we conducted a study on the CO2 uptake pattern of S. truncata, in a growth chamber and a greenhouse according to phylloclade maturity. The both the growth chamber and a greenhouse, mature phylloclades exhibited night CO2 uptake (Jung et al. 2023). S. truncata absorbs CO2 at night when ventilation is unnecessary.

    In the previous studies, Phalaenopsis grown under elevated CO2 level of 800 μmol·mol-1 exhibited increased biomass production (Kim et al. 2017). Elevated CO2 levels of either 800 or 1200 μmol·mol-1 enhanced flower production and shortened the flowering time in Phalaenopsis (Cho et al. 2019). However, the response of ornamental CAM plants to elevated CO2 was inconsistent and did not always yield positive outcomes (Croonenborghs et al. 2009). Phalaenopsis grown under high CO2 (1600 μmol·mol-1) levels resulted in flower bud abortion, which negatively impacted flower production (Kim et al. 2017). This suggests that there exists an optimal elevated CO2 level and duration for growth and flowering. Elevated CO2 can alter plant nutrient conditions and limited nutrients can reduce plant leaf area and photosynthesis (Mu et al. 2016). The decrease in leaf size under elevated CO2 and the non-significant changes of the net CO2 uptake under elevated CO2 with light control (Cho et al. 2019;Song et al. 2019;Yun et al. 2018) may be interpreted as sink limitation of long-term elevated CO2 supply. To alleviate the sink limitation of plants, manipulation of light level or fertility needs to be re-adjusted under elevated CO2 (Frantz and Ling 2011).

    The elevated CO2 has been widely used as a gas fertilizer in greenhouse cultivation for vegetable cultivation, particularly recently, as greenhouse technologies have improved (Bisbis et al. 2018). However, research on ornamental CAM plants is scarce. This study was conducted on the growth and photosynthetic response of Schlumbergera truncata under nighttime elevated CO2.

    Materials and Methods

    Plant materials and growth conditions

    On December 2022, the cuttings were planted, 12 cuttings per 10 cm pot, at a commercial greenhouse (‘Sang Ah Farm’, Goyang, Korea, latitude 37°N, longitude 126°E). 8-months after cutting, Schlumbergera truncata ‘Red Candle’ was transported to Seoul Women’s University in Seoul, Korea (latitude 37°N, longitude 127°E). The experiment was conducted at the information communication technologies (ICT) smart greenhouse at Seoul Women’s University from 14 August 2023 to 25 December 2023. Plants were transplanted into a 15 cm plastic pot filled with a soil mixture (perlite:peatmoss = 7:3, v/v). The air temperature of the cultivation periods was controlled at 23/20°C (day/night) and the relative humidity was maintained at 71/82% (day/night). Temperatures and relative humidity were automatically recorded at 1-minute intervals using a data logger (SH-VT250, Soha Tech, Korea), and the data are shown in Figs. 1A and 1B. Black-out curtains were used to shade the plants from 17:00 to 08:00 hours between 9 October to 8 November 2023, to induce flower bud formation. After 10 days under a short-day photoperiod, benzylamino purine 100 mg·L-1 was sprayed once at a rate of 10 mL per pot.

    CO2 supply

    Two levels of ambient (≈ 400 μmol·mol-1) and elevated CO2 (≈ 1000 μmol・mol-1) were applied to the plants for 10 h from 20:00 to 06:00 hours for 8 weeks after treatment (WAT). Elevated CO2 was supplied with pure CO2 from compressed gas cylinders (Bottle CO2 ≥ 99%) (Seoul Specialty Gases Co., Ltd., Seoul, Korea). CO2 was emitted upward from the ground through the polyvinyl chloride (PVC) pipe with holes drilled. The greenhouse was divided into an ambient CO2 section and an elevated CO2 section for CO2 treatment. The volumes of the ambient and elevated CO2 treatment spaces were 104.85 m³ and 69.9 m³, respectively. The two treatment areas were not completely sealed, so the ambient CO2 concentration was affected by nighttime CO2 enrichment. The average nighttime CO2 concentration in the ambient CO2 treatment section was 406 μmol·mol-1, which does not differ significantly from the average atmospheric CO2 concentration of 419 ppm in 2023 (NOAA 2024). The CO2 concentrations were monitored using a CO2 analyzer (SH-VT250AS, Aion Inc, Daejeon, Korea). The data are shown in Fig. 1C.

    Data collection

    The number of branches and phylloclades, mature phylloclade length and width, and immature phylloclade length and width were measured from 9 plants every 2 weeks during 8 WAT. The length and width of mature and immature phylloclades were measured continuously on the same phylloclade from 0 WAT. The number of phylloclades was measured with the phylloclade having lengths of ≥ 5 mm. For the dry mass measurements, the plants were cut into shoots, and roots at 8 WAT. The dry mass of shoots and roots was measured after drying the fresh plants in an oven at 70°C for 3 days.

    Photosynthetic characteristics were measured on the mature and immature phylloclade using a portable photosynthesis system (Li-6400XT, Li-Cor Inc., Lincoln, NE, USA) equipped with a clear chamber (6400-08, Li-Cor., NE, USA). The measurements were taken at 10:00 to 14:00 hours (mid-day) and 22:00 to 02:00 hours (mid-night) at 6 and 8 WAT. The photosynthetic characteristics were measured by selecting the most immature phylloclade at the time of measurement and the mature phylloclade connected to it. The length and width of mature and immature phylloclade using photosynthesis measurements were at 6 and 8 WAT are shown in Table 1. The air temperature in the chamber was set to match ambient and relative humidity, ranging from 55 to 70%. The CO2 concentration inside the chamber was maintained at 400 μmol·mol-1 CO2 (ambient CO2) and 1000 μmol·mol-1 CO2 (elevated CO2), which equals the level in the greenhouse. The net CO2 uptake, water-use efficiency (WUE), stomatal conductance (gs), and transpiration rate were measured. Gas exchanges were measured with 3 replicated plants per treatment. The value of WUE is calculated using the equation.

    WUE (water-use efficiency) = net CO 2  uptake ÷ transpiration rate

    WUE (water-use efficiency) = net CO2 uptake ÷ transpiration rate

    The chlorophyll fluorescence parameter the maximum photochemical efficiency of PSII (Fv/Fm) was measured by using a portable pulse amplitude modulation fluorometer (JUNIOR PAM, Walz, Effeltrich, Germany). Before the measurements, the phylloclades were adapted to darkness for 15 min. The matured phylloclade was selected for measurement. Fv/Fm values were measured from 10:00 to 12:00 hours on 5 plants per treatment after 12 WAT.

    The number of flower buds of ≥ 5 mm was counted for each plant every 2 days. Days to flowering were measured from the start of CO2 enrichment to flowering. Flowering was defined as the full expansion of the petals of the first flower per pot.

    Statistical analysis

    Statistical analyses were performed using the R program for version 4.2.3 (Development Core Team, Vienna, Austria). Statistical significance was determined using the Student’s t-test with p-values < 0.05 and one-way analysis of variance (ANOVA) with a post hoc Tukey test (p < 0.05). Graphical analysis was performed using SigmaPlot program version 10.0 (Systat Software Inc., CA, USA).

    Results

    Phylloclade growth and plant biomass

    The immature phylloclade width was significantly increased in plants grown under ambient CO2 than those under elevated CO2 (Table 2). At 0 to 8 WAT, the mature phylloclade width and length, and the immature phylloclade length, did not show significant differences among the CO2 treatments. The number of branches and phylloclade were not significantly different at 0 and 2 WAT than those of CO2 treatments. At 4 to 8 WAT, the number of branches and phylloclades were significantly greater in plants grown under ambient CO2 than those under elevated CO2 (Figs. 2A and 2B). The shoot and root dry mass was not significantly different among the CO2 treatments (Table 3). The immature phylloclade width, number of branches, and number of phylloclades were negatively correlated with increasing CO2 levels (r = -0.6810, -0.6020, and -0.6766) (Table 5).

    Photosynthetic characteristics and maximum quantum yield of PSII (Fv/Fm)

    The net CO2 uptake rate was significantly affected by phylloclade age and the interaction between phylloclade age and CO2 uptake time at 6 and 8 WAT (Table 4). At 6 WAT, net CO2 uptake was the highest in mature phylloclades of plants grown under both ambient and elevated CO2 at night, at 2.51 and 1.30 μmol·CO2·m-2·s-1, respectively, but there was no statistical significance (Fig. 3A). Immature phylloclades exhibited CO2 uptake only during the day at 6 WAT but showed uptake during both day and night at 8 WAT (Fig. 3B). The gs did not show a significant difference among the CO2 treatments at 6 and 8 WAT (Figs. 3C and 3D). The gs was significantly affected only by CO2 uptake time at 6 and 8 WAT (Table 4). The WUE did not significantly differ among the CO2 treatments at 6 and 8 WAT during the day (Figs. 3E and 3F). The WUE was significantly affected by phylloclade age, net CO2 uptake time, and the interaction between phylloclade age and CO2 uptake time at 6 and 8 WAT (Table 4). The WUE of mature and immature phylloclades at night increased as CO2 levels increased (r = 0.7462 and 0.9312, respectively) (Table 5). The Fv/Fm, an indicator of PSII’s maximum quantum yield, was 0.760 in plants grown under elevated CO2, which was not significantly different from the ambient CO2 of 0.735 (Table 6).

    Flowering

    The floral buds first appeared at 77 days after treatment (DAT) in plants grown under elevated CO2 and at 81 DAT in those under ambient CO2 (Fig. 4). At 123 DAT, plants grown under elevated CO2 had 82.7 floral buds, compared to 72.1 buds for those under ambient CO2. However, this difference was not statistically significant. The flower length and width did not show significance among the treatments (Table 7). The days to flowering were 121.7 days for plants grown under ambient CO2 and 123.7 days for those grown under elevated CO2, but the difference was not significant.

    Discussion

    Elevated CO2 benefits ornamental plant production through plant growth to improve the yields and qualities of flowers, but some plant species may exhibit unresponsive or opposite effects in response to elevated CO2 (Hussain et al. 2021;Xu et al. 2014). Leaf senescence or visible injuries, such as chlorosis, necrosis, and leaf curling, are observed in some plants at higher CO2 levels (Mortensen 1987). In this study, no visible phylloclade injuries were observed in plants grown under elevated CO2. However, there was a decrease in phylloclade growth in plants grown under elevated CO2 compared to those grown under ambient CO2 (Fig. 2 and Table 2).

    During 4 years of CO2 enrichment, the growth of beech and the amount of its nutrients decreased (Hagedorn et al. 2002). Limited nutrients can reduce plant leaf area and photosynthesis (Mu et al. 2016). The number of leaves increased in the plants grown under 800 and 1600 μmol·mol-1 during 32 or 36 weeks of treatments with increased net CO2 uptake, and Phalaenopsis was fertigated with water-soluble fertilizer of 20N-8.7P-16.7K at electrical conductivity ranged from 0.8 to 1.0 dS・m-1 (Song et al. 2019;Yun et al. 2018). Naing et al. (2016) suggested that the leaf growth rate increased in the plants grown under CO2 enrichment (1000 μmol·mol-1) and with a light level of 250 μmol·m-2·s-1. Cho et al. (2019) observed an increase in floral buds and flowers in Phalaenopsis Queen Beer ‘Mantefon’ when plants were grown under a light level of 260 ± 40 μmol·m-2·s-1 with 800 μmol·mol-1 CO2 compared to those grown under 400 μmol·mol-1 CO2. The enhanced photosynthetic rates due to elevated CO2 more than doubled under high-light conditions compared to low-light conditions in sweetgum trees (Herrick and Thomas 1999). However, this study did not provide additional fertilizer or supplemental light. These results suggest that environmental conditions (e.g., light and nutrients) should be considered when cultivating plants under elevated CO2 to maintain high plant quality.

    Elevated CO2 increases carbohydrate production in plants, but as they mature, the limited ability to create new storage leads to a decline in net photosynthesis (Thomas and Strain 1991). Similarly, the mature phylloclade of S. truncata showed higher net CO2 uptake at night in plants grown under ambient CO2 compared to those grown under elevated CO2 at 6 WAT (Fig. 3A). Long-term elevated CO2 could lead to photosynthetic acclimation, potentially reducing the photosynthetic machinery and leaf photosynthetic potential (Griffin and Seemann 1996). Studies support these responses: in Opuntia ficus-indica, the stomatal frequency decreased by 20% under elevated CO2 compared to ambient CO2. Consequently, CO2 uptake and water vapor conductance were affected (Nobel 1999). At 8 WAT, immature phylloclades grown under ambient CO2 did not uptake CO2 at night, while immature phylloclades grown under elevated CO2 did uptake CO2 at night (Fig. 3B). Once the facultative CAM plants, photosynthesis can switch from C3 to CAM under abiotic stress (such as atmospheric CO2 concentration, drought, salinity, photoperiod, light, etc.) (Qiu et al. 2023). During the daytime in Clusia pratensis at its C3 state, the 800 ppm CO2 treatment showed no effect on nocturnal CO2 exchange, indicating the absence of CAM induction (Winter and Holtum 2014). These data suggest that CO2 concentration may not be the CAM-inducing factor. However, previous studies treated CO2 during the daytime, so there is a difference between this study, which treated CO2 at night. The gs of mature phylloclades exhibiting CAM characteristics were lower in plants grown at elevated CO2 compared to those grown at ambient CO2. Stomatal behavior is another specific feature of CAM plants. Stomatal movement is controlled by many different factors, including light and CO2 concentration (Guan et al. 2020). Guard cells form epidermal stomatal gas-exchange valves in plants and regulate the aperture of stomatal pores in response to changes in the CO2 concentration in leaves (Engineer et al. 2016). CAM plants exhibit 2 to 5-fold higher WUE compared to C3 and C4 plants (Nobel and Barrera, 2004). In this study, at 8 WAT, nighttime CO2 uptake was observed exclusively in the immature phylloclades of the elevated CO2 treatment. The WUE was significantly higher elevated CO2 than those grown under ambient CO2 at 8 WAT (Fig. 3F).

    Measured chlorophyll fluorescence can be used to predict, monitor, and identify stress in plants (Kalaji et al. 2016). The presence of low Fv/Fm will indicate substantial photoinhibition or down-regulation of PSII (Murchie and Lawson 2013). Pulse-amplitude modulated fluorescence measurements have been utilized to detect alterations in plant physiological status in reaction to shifting environments before observable morphological changes occur (Zha et al. 2017). Fv/Fm is not significantly different among the CO2 treatments; however, there were differences in plant growth among the CO2 treatments observed during the vegetative growth stage (Table 5). Reduced values of Fv/Fm indicate photoinhibition, decreased photosynthetic capacity, and a reduced number of triplet states in functional reaction centers when plants are exposed to stress (Na et al. 2014). Fv/Fm measurements were conducted after discontinuing CO2 treatment, suggesting that stress was induced during the vegetative growth stage in plants treated with 1000 μmol·mol-1 of CO2 treatment.

    The effects of elevated CO2 on flowering time are not as well understood and vary widely among species (Springer and Ward 2007). flowering characteristics were not significant among the CO2 treatments. Despite the photosynthetic acclimation of wheat plants to high levels of CO2, total soluble sugars in grains increased (Sinha et al. 2011). Although photosynthetic rates decreased, it is possible that the increase in sugars led to an increase in the number of floral buds.

    In conclusion, this study showed that elevated CO2 significantly decreased the growth of S. truncata. The immature phylloclade width, number of phylloclades, and branches were significantly higher plant grown under ambient CO2 than those of the elevated CO2. The flowering characteristics did not significantly differ among the CO2 treatments.

    Acknowledgments

    This study was carried out with the grants research funds of Seoul Women’s University, Korea (2024-0054).

    Figure

    FRJ-32-3-120_F1.gif

    The temperature (A), relative humidity (B), and CO2 concentrations (C) in a greenhouse for Schlumbergera truncata ‘Red Candle’ with ambient and elevated CO2 over 8 weeks of the everyday interval from 14 August to 8 October 2023 (56 days). Vertical bars represent the standard deviation of the means (n = 56).

    FRJ-32-3-120_F2.gif

    The number (No.) of branches (A) and phylloclades (B) of Schlumbergera truncata ‘Red Candle’ grown under ambient and elevated CO2 for 8 weeks. Vertical bars represent the standard error of the means (n = 9). Statistical analysis was performed using a Student’s t-test. The significance level of p-values is indicated as follows: *p < 0.05; **p < 0.01.

    FRJ-32-3-120_F3.gif

    The net CO2 uptake (A and B), the stomatal conductance (gs) (C and D), and water-use efficiency (WUE) (E and F) of Schlumbergera truncata ‘Red Candle’ grown under ambient and elevated CO2 at 6 weeks after treatment (A, C, and E) and 8 weeks after treatment (B, D, and F). Vertical bars represent the standard error of the means (n = 3). Different letters indicate statistically significant differences as determined by the results of Tukey’s HSD test at p < 0.05.

    FRJ-32-3-120_F4.gif

    The number (No.) of floral buds of Schlumbergera truncata ‘Red Candle’ grown under ambient and elevated CO2 for 8 weeks. Vertical bars represent the standard error of the means (n = 9). Statistical analysis was performed using a Student’s t-test. The significance level of p -values is indicated as follows: *p < 0.05.

    Table

    The mature and immature phylloclade length and width of Schlumbergera truncata ‘Red Candle’ plants were used to measure the photosynthetic characteristics at 6 and 8 weeks after treatment.

    <sup>z</sup>Mean ± standard deviation (n = 3).

    The mature and immature phylloclade length and width of Schlumbergera truncata ‘Red Candle’ grown under ambient and elevated CO2 for 8 weeks.

    <sup>z</sup>Mean ± standard error (n = 9).
    <sup>y</sup>Statistical analysis was performed using a Student’s <i>t</i> -test. The significance level of <i>p</i> -values is indicated as follows: <sup>**</sup><i>p</i> < 0.01.

    The fresh and dry weights of shoots and roots of Schlumbergera truncata ‘Red Candle’ grown under ambient and elevated CO2 at 8 weeks after treatment.

    <sup>z</sup>Mean ± standard error (n = 3).

    Output of three-way ANOVA for effects of CO2 level (ambient and elevated CO2), phylloclade age (mature and immature), and net CO2 uptake time (day and night) on net CO2 uptake, stomatal conductance (gs), and water-use efficiency (WUE) of Schlumbergera truncata ‘Red Candle’ grown under ambient and elevated CO2 at 6 and 8 weeks after treatment.

    Numbers represent <i>F</i> values - <sup>*</sup><i>p</i> < 0.05, <sup>**</sup><i>p</i> < 0.01, <sup>***</sup><i>p</i> < 0.001 levels, and ns denotes not significant.

    Pearson correlation coefficient for the variables of Schlumbergera truncata ‘Red Candle’ grown under ambient and elevated CO2 at 8 weeks after treatment.

    The maximum photochemical efficiency of PSII (Fv/Fm) of Schlumbergera truncata ‘Red Candle’ grown under ambient and elevated CO2 at 12 weeks after treatment.

    <sup>z</sup>Mean ± standard error (n = 5).

    The flower length, flower width, and days to flowering of Schlumbergera truncata ‘Red Candle’ grown under ambient and elevated CO2.

    <sup>z</sup>Mean ± standard error (n = 9).

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    1. SEARCH

    2. Journal Abbreviation : 'Flower Res. J.'
      Frequency : Quarterly
      Doi Prefix : 10.11623/frj.
      ISSN : 1225-5009 (Print) / 2287-772X (Online)
      Year of Launching : 1991
      Publisher : The Korean Society for Floricultural Science
      Indexed/Tracked/Covered By :

    3. Online Submission

      submission.ijfs.org

    4. Template DOWNLOAD

      Original Research
      Articles      국문 영문
      Review Articles 리뷰
      ★NEWTechnical Reports단보
      New Cultivar
      Introduction       품종

    5. 논문유사도검사

    6. KSFS

      Korean Society for
      Floricultural Science

    7. Contact Us
      Flower Research Journal

      - Tel: +82-54-820-5472
      - E-mail: kafid@hanmail.net