Abstract
Phalaenopsis (Phalaenopsis spp.) is the most important indoor potted plant worldwide. Tissue analysis is very important for managing fertilization practices but the effects of sampling position and plant maturity must be considered. However, there has been little research on the distribution of tissue carbon (C) and nitrogen (N) among leaves and changes of tissue C and N composition during various developmental stages in phalaenopsis. In this study, we thus determined the effects of leaf age, plant maturity, and cultivars on C and N partitioning in phalaenopsis. Overall, C concentration was more uniform and was less affected by the abovementioned factors investigated, whereas N concentration significantly decreased as leaves aged or as plants matured. In P. Sogo Yukidian ‘V3’, new expanding leaf had the highest N concentration of 2.72% of dry weight (DW) and seventh mature leaf had the lowest value of 1.48% DW. Results also indicate that N was not evenly distributed within a leaf, whereas N concentration gradually decreased from the leaf tip to the leaf base. The middle section of the second mature leaf is an appropriate tissue for sampling to obtain the representative N and C concentrations in phalaenopsis. As for the changes in C and N composition through five developmental stages, two cultivars were compared, including the large, white-flowered P. Sogo Yukidian ‘V3’ and the small, purple-flowered P. Sogo Lotte ‘F2510’. As the large-flowered ‘V3’ grew from deflasked plantlet to fully matured plant (18 months after deflasking) in a 10.5-cm pot, whole-plant N concentration decreased from 4.63% DW to 1.67% DW and C/N thus increased from 9.1 to 26.1. Despite the large difference in plant size, the small-flowered ‘F2510’ had a similar trend and values during vegetative growth stages. However, the two cultivars had different trends during reproductive stages. Tissue N concentration and C/N did not further change as mature large-flowered ‘V3’ plants were forced to flower. By contrast, tissue N concentration in small-flowered ‘F2510’ further decreased and C/N thus further increased, which was due to its small stored N pool. Major N sink organ shifted from roots to inflorescences during reproductive growth and the stored N in roots as well as in leaves was then used for flower development.
Phalaenopsis (the moth orchid) is currently the most important indoor potted flowering plant worldwide (Royal Flora Holland, 2017; U.S. Department of Agriculture, 2016). Growers normally produce phalaenopsis at high temperatures (>28 °C) to promote vegetative growth (Chen et al., 1994; Yoneda et al., 1991). With sufficient light (Wang, 1995), mature plants can then be forced to flower at lower temperatures (20 to 25 °C) (Lee and Lin, 1984; Yoneda et al., 1992). Although flowering of phalaenopsis is mainly controlled by low temperature, mineral nutrition also plays an important role in flowering (Lee and Lin, 1987; Poole and Seeley, 1978; Sheehan, 1961; Tanaka et al., 1988).
Ratio of tissue C and N is called C/N ratio. In the literature, high tissue C/N promotes reproductive growth; low C/N increases vegetative growth and may inhibit flowering (Klebs, 1918). In Pharbitis nil, seedlings with high tissue C/N were more sensitive to the inductive dark periods, which resulted in a higher flowering rate (Wada and Shinozaki, 1985). In Oncidium Gower Ramsey, there was a positive correlation between tissue C/N and flowering quality (Wang, 2011). Tissue analysis can directly reveal plant nutrient status, but sampling position and the effects of plant developmental stages must be considered to appropriately interpret the results. However, there has not been a significant amount of research on the distribution of tissue C and N and their partitioning during the development of phalaenopsis. The literature on how C and N affect growth and flowering of phalaenopsis is also limited.
The N concentration of mature leaves in phalaenopsis was between 1.93% DW and 2.83% DW (Poole and Sheehan, 1974). N concentration is affected by the location of leaf, cultivars (Poole and Sheehan, 1974), and N level in fertilizer (Wang and Konow, 2002). N concentration decreases as leaves became more mature in phalaenopsis (Poole and Sheehan, 1974). Susilo et al. (2013) compared N concentrations at different leaf locations in Phalaenopsis Sogo Yukidian ‘V3’ and found that new leaf had the highest N concentration of 2.31% and the sixth leaf had the lowest value of 1.16%. Kataoka et al. (2004) took five pairs of leaf discs, where each pair was symmetrically positioned with respect to the midrib, at five different distances from the leaf tip for sugar analysis. The second, third, and fourth leaf disc pairs from the leaf tip had almost the same amount of sugar, but the first and fifth pairs had different values. The literature indicates that C and N are not evenly distributed in the leaves of phalaenopsis (Kataoka et al., 2004; Poole and Sheehan, 1974; Susilo et al., 2013). Appropriate sampling position is thus crucial for correctly interpreting the results of tissue analysis.
Many orchids have enlarged stems called pseudobulbs, which can store water, carbohydrate, and minerals (Ng and Hew, 2000). Phalaenopsis does not have pseudobulbs, but its succulent leaves and roots have been proved to have storage function of N (Susilo et al., 2013). With 90% reduction in fertilizer during reproductive stage, flowering quality was only slightly reduced compared with the full-fertilization treatment in phalaenopsis and stored N became the major N source for inflorescence development (Susilo and Chang, 2014). Susilo et al. (2014) compared N concentrations of whole plant at five developmental stages in Phalaenopsis Sogo Yukidian ‘V3’ and found the N concentrations of young plant, just-matured plant, well-matured plant, plant with flower bud visible, and plant with 2/3 flowers opened were 2.00%, 2.35%, 2.18%, 1.82%, and 1.84%, respectively. Their data implied that a natural change, in the form of decreasing N concentration during development, might exist among cultivars in Phalaenopsis. By contrast, Lee and Wang (1997) did not find obvious change in tissue N concentration during 7 months of transition stage (between juvenile and mature stages) of a hybrid white-flowered phalaenopsis. Lei (2007) used fully mature white-flowered phalaenopsis (Phalaenopsis amabilis) as plant material and found no significant changes in N concentration during reproductive stages. Whether N concentration would naturally decrease or not during development among phalaenopsis cultivars needs to be further understood.
This study aimed to reveal the nature of tissue N and C in phalaenopsis and their progressive changes with plant growth and development; the similarities and differences between standard-type and miniature-type phalaenopsis in those regards were compared. From the data obtained, we hope to acquire important information regarding precise sampling and how to appropriately interpret the results of tissue analysis for phalaenopsis.
Materials and Methods
Expt. 1. Distribution of C and N in the leaves of phalaenopsis.
Experiment 1 was conducted to determine the appropriate sampling position for tissue C and N analysis and the effects of leaf age on C and N distribution in phalaenopsis. Vegetative, large, white-flowered phalaenopsis, Phalaenopsis Sogo Yukidian ‘V3’, were purchased from Oriental Star Orchids Group (Chiayi, Taiwan). Plants were 17 months old after deflasking and sphagnum moss was used as the growing medium. Each plant had seven matured leaves and one new expanding leaf, which was 50% to 70% the length of the first matured leaf. After purchase, the plants were allowed to recover in a 30/25 °C (day/night) growth chamber for 2 d and then sampling was performed. The second mature leaf was equally separated into five parts from the tip to the base by length. New leaf and first, third, fifth, and seventh mature leaves were also harvested for tissue C and N analysis (Fig. 1). Fresh weight and DW were recorded. The whole-leaf DW, N concentration, and C concentration of the second leaf were calculated from the five sections. A completely randomized design with 10 single-plant replications was used.
Expt. 2. Changes of tissue C and N composition in phalaenopsis during various developmental stages.
To determine the effects of plant maturity and cultivar on tissue C and N concentrations, two phalaenopsis cultivars with different plant size were used for investigating the C and N distribution at five different developmental stages. Plants of the standard-type, large, white-flowered phalaenopsis, P. Sogo Yukidian ‘V3’ were purchased from Tai-Ling Biotech., Inc. (Tainan, Taiwan). Stage T was tissue-culture plantlet. Stages S, M, and L represented vegetative growth stages in 4.5-, 8.5-, and 10.5-cm pots, respectively. Stage F was reproductive growth stage in 10.5-cm pots with half flowers opened. For stages S, M, L, and F, plants have been cultivated in sphagnum moss for 4.5, 10.5, 18, and 27 months after deflasking, respectively. Plants of another cultivar, the miniature-type, small, purple-flowered phalaenopsis P. Sogo Lotte ‘F2510’ were purchased from Sogo Team Co., Ltd. (Kaohsiung, Taiwan). Stage T was deflasked tissue-culture plantlet. Stages 2M, 4M, and 6M indicated vegetative growth stages in sphagnum moss in 5.1-cm pots after 2, 4, and 6 months out of flask, respectively. Stage F was reproductive growth stage in 5.1-cm pots, 9 months after deflasking and with half flowers opened. The average concentration of fertilizer N applied during the cultivation of both cultivars was 50 mg·L−1 N. Plants were sampled directly after purchase. The sphagnum moss was removed by hand and the plants were rinsed with tap water. Plants were dissected into roots, shoot, and inflorescence (if present) for tissue C and N analysis. Fresh weight and DW were both determined. The experiment was carried out in a completely randomized design with 10 single-plant replications.
Expt. 3: Changes of tissue C and N composition in phalaenopsis during reproductive stages.
The aim of this experiment was to investigate the changes of C and N partitioning during reproductive stages. Vegetative, small, purple-flowered phalaenopsis (P. Sogo Lotte ‘F2510’) plants were purchased from Sogo Team Co., Ltd. The age of the mature plants was 7 months after deflasking. Plants were forced in a 25/20 °C phytotron with photosynthetic photon flux (PPF) not exceeding 300 µmol·m−2·s−1 at midday for 3 months and then transferred to a greenhouse with 27.0 °C average temperature and average PPF of 154 µmol·m−2·s−1. Fertigation was performed using a water-soluble 20N–8.6P–16.6K fertilizer (Peters Professional 20–20–20; Everris NA, Dublin, OH) at 50 mg·L−1 N. Second and third spikes were removed as it reached 0.5 cm to ensure uniformity of plant materials. Plants were sampled at seven stages. Stage 1: Day 0, the day forcing started; Stage 2: Day 10; Stage 3: spiking; Stage 4: 40 d after spiking; Stage 5: bud visible; Stage 6: first flower opened; Stage 7: half flowers opened. Plants were dissected into roots, shoot, and inflorescence (if present) for tissue analysis. Twelve single-plant replications were used in this experiment with a completely randomized design.
Tissue C and N analysis.
After drying at 70 °C to constant weight, samples were ground with high speed blade grinder (RT-02; Rong Tsong Precision Technology, Taichung, Taiwan) or tissue grinder (SH-100; Kurabo Industries Ltd., Osaka, Japan). Between 2.5 and 3.5 mg, ground samples were packed into 8 × 5-mm tin capsules (Elemental Microanalysis, Okehampton, UK). C and N concentrations were determined by combustion method. A CN Analyzer (Flash EA 1112 Series; Thermo Fisher Scientific, Rodano, Milano, Italy) was used, with combustion and reduction temperatures of 900 and 680 °C, respectively. Atropine (C17H23NO3, A0132; Sigma, St. Louis, MO) was used as a standard. The content of C or N was obtained by multiplying DW by the respective C or N concentration.
Statistical analysis.
Data were subjected to analysis of variance using completely randomized design. Means separation was performed by the least significance difference test at P ≤ 0.05. Statistical analysis was completed using Costat (version 6.1; CoHort Software, Monterey, CA).
Results
Expt. 1. Distribution of C and N in the leaves of phalaenopsis.
The C concentrations of whole leaf in large, white-flowered phalaenopsis ‘V3’ were between 43.0% DW and 43.8% DW. Although there were statistical differences in C concentrations among leaves at various locations, the difference in values was relatively small and without an obvious increasing or decreasing trend (Table 1). N was not evenly distributed among leaves; N concentration decreased as leaves became more mature (from top to bottom). New leaf had the highest value of 2.72%, and the first mature leaf had the second highest value of 2.14%. The N concentrations of the second to the fifth mature leaves were between 1.86% and 1.92%, which were relatively stable and with no significant difference. The N concentration of the seventh mature leaf was 1.48%, which was the lowest value among all leaves (Table 1). As leaves became more mature, C/N ratio increased because of the decrease in N concentration. The seventh mature leaf had the highest C/N ratio of 29.5, and the new leaf had the lowest value of 16.1. The C/N ratios of second to fifth mature leaves were between 22.7 and 23.2. The first and second mature leaves had higher DW and C content compared with all other leaves. The first mature leaf had the highest N content of 33.3 mg, higher than that of second mature leaf (28.8 mg) and other leaves (Table 1).
Changes of dry weight (DW) and carbon (C) and nitrogen (N) concentrations and contents as well as C/N ratio in Phalaenopsis Sogo Yukidian ‘V3’ at different leaf locations and positions of the second mature leaf.
In phalaenopsis ‘V3’, the C concentrations of five sections in second mature leaf were between 43.2% and 43.8%, which also had no obvious increasing or decreasing trend (Table 1). N was not evenly distributed among different sections of the second mature leaf, which decreased from the leaf tip to the base. Sections 1 and 2 had the highest N concentrations of 2.32% and 2.27%, respectively. The N concentration of Section 3 was 1.96%, and Section 5 had the lowest value of 1.56% (Table 1). C/N ratio increased from the leaf tip to the base because of a decreasing trend in N concentration. Section 5 had the highest C/N ratio of 28.0; Sections 1 and 2 had the lowest values of 19.0 and 19.1, respectively. C/N ratio of Section 3 was 22.3, which was the closest value to that of whole second mature leaf (22.7). Sections 3, 4, and 5 had the highest DW and C content among all sections. Sections 2 and 3 had the highest N contents of 7.0 and 6.7 mg, respectively (Table 1).
Expt. 2. Changes of tissue C and N composition in phalaenopsis during various developmental stages.
For the changes of whole-plant C concentration in vegetative growth stages, the two cultivars exhibited different trends but the difference is small in value; C concentrations of the two cultivars were both between 41.4% and 43.1% (Fig. 2A and B). On the other hand, both cultivars shared a similar decreasing trend in whole-plant N concentration as plants became more mature. In the large, white-flowered phalaenopsis (P. Sogo Yukidian ‘V3’), N concentration decreased from 4.63% to 1.67% as growth stage progressed from T to L (Fig. 2C). In the small, purple-flowered phalaenopsis (P. Sogo Lotte ‘F2510’), N concentration decreased from 3.80% to 2.24% as growth stage proceeded from T to 6M (Fig. 2D). The C/N ratio increased as plants became more mature in both cultivars because of the decrease in N concentration. In the large, white-flowered ‘V3’, C/N increased from 9.1 to 26.1 as growth stage progressed from T to L (Fig. 2E). In the small, purple-flowered ‘F2510’, C/N ratio increased from 11.3 to 18.6 as growth stage proceeded from T to 6M (Fig. 2F). The changes of C concentration, N concentration, and C/N ratio of respective organs, i.e., shoot and roots, were similar to those of whole plant (data not shown).
During reproductive stages (from L to F for ‘V3’ and from 6M to F for ‘F2510’), the two cultivars had different trends in C concentration, N concentration, and C/N ratio. In the large, white-flowered ‘V3’, C concentration of shoot decreased from 43.6% to 41.8% and that of roots decreased from 42.4% to 40.8% (Table 2). However, flowering did not further affect N concentration and C/N ratio. In the small, purple-flowered ‘F2510’, C concentration of shoot increased from 41.0% to 42.7% and that of roots increased from 42.5% to 43.3% (Table 3). N concentration of shoot decreased from 1.98% to 1.52% and that of roots decreased from 2.90% to 1.71% (Table 3). C/N ratio of shoot increased from 20.8 to 28.1 and that of roots increased from 14.9 to 26.5 (Table 3). C concentrations of inflorescences were higher than those of shoot and roots in both cultivars. N concentration of inflorescence was lower than those of shoot and roots (at the stage of half flowers opened) in large, white-flowered ‘V3’, but in contrast, higher N concentration was found in the inflorescence of small, purple-flowered ‘F2510’ compared with those found in its shoot and roots (Tables 2 and 3).
The effect of flowering on carbon (C) and nitrogen (N) concentrations and contents as well as C/N ratio in Phalaenopsis Sogo Yukidian ‘V3’at different plant parts.
The effect of flowering on carbon (C) and nitrogen (N) concentrations and contents as well as C/N ratio in Phalaenopsis Sogo Lotte ‘F2510’ at different plant parts.
Expt. 3. Changes of tissue C and N composition in phalaenopsis during reproductive stages.
Small, purple-flowered ‘F2510’ spiked at 22 d after forcing; first flower bud was visible at 76 d, and half flowers opened at 115 d after forcing. Total flower number was 10.5 (data not shown). During the reproductive stage (from forcing to half flowers anthesis), total leaf number only slightly increased from 7.0 to 7.7 and no significant change in the length of the first mature leaf was found (data not shown).
From forcing (Stage 1; Day 0) to half flowers opened (Stage 7; Day 115), DW of whole plant increased from 1.16 to 2.13 g, N content increased from 21.7 to 29.5 mg, and C content increased from 507.5 to 974.6 mg (Table 4). These data indicate that the plant was actively assimilating during the forcing period for the initiation and development of inflorescences. Because the rate of increment for DW was higher than that of N, N concentration decreased from 1.88% to 1.39%. C concentration increased from 43.8% to 45.8%; due to the decrease in N concentration, C/N ratio increased from 23.0 to 33.0 (Table 4).
Changes of dry weight (DW) and carbon (C) and nitrogen (N) concentrations and contents as well as C/N ratio in Phalaenopsis Sogo Lotte ‘F2510’ at various reproductive stages.
During spike initiation (Stages 1 to 3), DW gain rates of shoot and roots were 5.15 and 6.21 mg·d−1, respectively (Table 5). It is worth noting that during spike elongation period (Stages 3 to 5), DW gain rates of shoot and roots decreased to 2.32 and 2.20 mg·d−1, respectively. Inflorescence had the highest DW gain rate of 4.29 mg·d−1 during spike elongation, which further increased to 11.01 mg·d−1 during flower development (Stages 5 to 7). Shoot and roots had negative gains of DW during flower development, indicating a decrease of DW in vegetative organs (Table 5). The trend of C gain rate was similar to that of DW gain rate. During spike initiation (Stages 1 to 3), N gain rates of shoot and roots were 26.9 and 74.3 μg·d−1, respectively. Roots accounted for 73.4% of total N gain. As spikes elongated (Stages 3 to 5), N gain rates decreased to 1.9 μg·d−1 for shoot and −7.2 μg·d− for roots (Table 5). Inflorescence had the highest N gain rate of 61.8 μg·d−1 during spike elongation, and it further increased to 151.4 μg·d−1 during flower development (Stages 5 to 7). Shoot and roots had negative gains of N during flower development, which were −41.0 and −45.8 μg·d−1, respectively (Table 5).
Rate of dry weight, carbon (C), and nitrogen (N) gain in Phalaenopsis Sogo Lotte ‘F2510’ during various reproductive stages.
Discussion
Sampling position for C and N analysis in phalaenopsis.
N is an important mineral nutrient which can significantly affect growth and flowering of phalaenopsis. Appropriate N level in fertilizer is 100–200 mg·L−1 N for phalaenopsis, which promotes vegetative growth, including increasing total leaf number, total leaf area, fresh weight, and DW (Lee and Lin, 1987; Poole and Seeley, 1978; Tanaka et al., 1988). Flowering quality indices, including length of spike, total flower number, and number of spikes, also increase with N fertilization (Wang and Gregg, 1994). On the other hand, excessive N fertilization (300–400 mg·L−1) can result in reduced flower number (Lei, 2007; Wang, 2003). Symptoms of N deficiency include defoliation, considerable reduction of total leaf area, and chlorosis in phalaenopsis (Yoneda et al., 1997). The critical N concentration for N deficiency symptoms to become apparent was 0.6% to 0.9% in leaf of phalaenopsis (Yu, 2012).
Tissue analysis can directly reveal the nutrient status in plants, but sampling position must be considered. In the literature, N was found to be unevenly distributed in phalaenopsis, where upper leaves had higher N concentration (Poole and Sheehan, 1974; Susilo et al., 2013). Results from this research demonstrated that N concentrations of whole leaf in phalaenopsis were between 1.48% and 2.72% and upper leaves had higher N concentrations (Table 1). The new leaf is still expanding, which makes it hard to obtain uniform sampling and thus it is not suitable for sampling. Other research suggested the second mature leaf to be the appropriate part for tissue analysis (Mantovani et al., 2015). Results from this research indicated that the second to fifth mature leaves had relatively stable N concentration and thus are suitable leaves for tissue N analysis.
To minimize the injury to plants and to facilitate analysis work that follows, sampling a section of leaf instead of a whole leaf could be made if an appropriate leaf part is selected. N is not evenly distributed in a single leaf, thus sampling position on a leaf may affect the result of tissue analysis. In the second mature leaf, N concentration of Section 3 (middle part) was 1.96%, which was very close to the whole leaf value 1.92% (Table 1). C concentration of Section 3 (43.5%) was almost the same with that of the whole leaf (43.6%). C/N ratio of Section 3 was 22.3, which was close to the whole-leaf value of 22.7 (Table 1). Kataoka et al. (2004) also indicated that middle part of the leaf is suitable for carbohydrate analysis in phalaenopsis. We conclude that the middle part of the second mature leaf is appropriate for tissue analysis to obtain representative N concentration in phalaenopsis.
Changes of tissue C and N composition in phalaenopsis during various developmental stages.
Major developmental events like flushing, flowering, and fruiting often occurred with partitioning of N and C in plants. In different developmental stages, the distribution of N and C in tissue is also different (Malip and Masri, 2006; Suto et al., 1984; Tahir et al., 2003; Xia, 1993; Yong and Hew, 1995). In phalaenopsis ‘V3’, concentration of N decreased as plants became more mature (Susilo et al., 2014). In this study, we further examined the C and N changes from tissue-culture plantlet stage to half flowers opened stage and compared the similarity and difference between two cultivars. The results confirmed that, in both phalaenopsis cultivars, tissue N concentration decreased with plant development (Fig. 2C and D). A high N concentration was detected in tissue-culture plantlet (4.6% in ‘V3’; 3.8% in ‘F2510’). High tissue N concentration in tissue-culture plantlet was also reported in Phalaenopsis Sogo Yukidian ‘V3’ and Phalaenopsis amabilis, which might be caused by high N level (708 mg·L−1; 50.6 mm N) in the tissue-culture medium (Chen, 2014).
N level in fertilizer significantly affects tissue N concentration in phalaenopsis (Poole and Seeley, 1978). Some growers deliberately decrease or even eliminate N supply before forcing to raise tissue C/N ratio and to enhance flowering in phalaenopsis. In this research, N level in fertilizer during cultivation was maintained relatively stable at 50 mg·L−1 in both cultivars. Results showed that C/N ratio naturally increased as plants became more mature (Fig. 2E and F), without a deliberate decrease in N supplied, and those plants can be successfully forced without a decline in flowering quality. A further study is needed to quantify the effects of short-term N application on tissue C and N composition and flowering performance in phalaenopsis.
Flowering is the most important event in plant development. In Oncidium orchid, C/N ratio of back pseudobulbs decreased during flowering (Wang, 2011). Another research showed that concentrations of total nonstructural carbohydrate in the first back shoot and the second back shoot decreased during flowering in Oncidium (Hew and Ng, 1996). Results from both studies mentioned previously indicated that stored nutrient might be mobilized to support the development of inflorescences. In Expt. 2, two cultivars had different trends in changes of N concentration during reproductive growth (Tables 2 and 3). This may be due to different sizes of N pool. In large white-flowered ‘V3’, N content of mature plant in 10.5-cm pot was 187 mg (calculated from Table 2; i.e., 108 + 79 mg); by contrast, 6-month-old small purple-flowered ‘F2510’ had only 20.8 mg of N content (calculated from Table 3; i.e., 12.9 + 7.9 mg). With small-sized N pool, small-flowered ‘F2510’ at Stage 6M could not fully support the development of inflorescence (13.0 mg N) without a decrease in N concentration in shoot and roots (Table 3). By contrast, with a sufficient N pool, the large-flowered ‘V3’ had no significant changes in N concentration and C/N ratio from mature-plant stage to half flowers open stage (Table 2). Lei (2007) used large, white-flowered phalaenopsis (Phalaenopsis amabilis) in 10.5-cm pot as plant materials and found no significant changes in N concentration during reproductive stages, which might also be due to a sufficient N pool. In Expt. 3, N concentration decreased from 1.88% to 1.39%, as growth stages of 7-month-old ‘F2510’ progressed from Stage 1 (0 d after forcing) to Stage 7 (half flowers opened; Table 4). This result was consistent with that of Expt. 2, where N concentration decreased during reproductive stage in small purple-flowered ‘F2510’ (Table 3).
Susilo et al. (2013) demonstrated that newly grown leaves and newly formed roots were major N sinks in vegetative growth stage, whereas stalks and flowers were major N sinks in the reproductive stage of phalaenopsis. In Expt. 3, major N sinks shifted from roots to inflorescences during forcing (Table 5). By using stable isotope 15N as a tracer, Susilo et al. (2014) determined that stored N contributed 43% of N in inflorescences at visible bud stage in large white-flowered ‘V3’. In this research, we calculated the difference of N content between different stages in each organ, to determine the partitioning of N in various periods of growth. In spike initiation stage, ratio of newly gained N in shoot and roots was 26.6% and 73.4%, respectively [i.e., 26.9:74.3 (calculated from Table 5)]. This observation suggested that root was the major sink organ during spike initiation stage. The inflorescence became a major N sink organ at spike elongation stage with the highest N gain rate of 61.8 μg·d−1 (Table 5), of which newly gained N (from fertilizer) contributed about 88.3% [i.e., (61.8–7.2)/61.8; calculated from Table 5] of total N gained in inflorescences. During flower development stage, shoot and roots had a negative N gain rate, indicating that these organs became N sources, which accounted for 27.1% (i.e., 41.0/151.4; calculated from Table 5) and 30.3% (i.e., 45.8/151.4) of total N gain in inflorescences, respectively. Total N gain in inflorescences in the three stages was 9.24 mg [i.e., (61.8 μg·d−1 * 54 d) + (151.4 μg·d−1 * 39 d); calculated from Table 5], while total N loss in shoot and roots were −1.50 mg [i.e., (1.9 μg·d−1 * 54 d) + (−41.0 μg·d−1 * 39 d)] and −2.18 mg [i.e., (−7.2 μg·d−1 * 54 d) + (−45.8 μg·d−1 * 39 d) μg], respectively. Stored N contributed 40% [i.e., (1.50 + 2.18)/9.24 mg] of N in inflorescences at half flowers opened stage (calculated from Table 5), which is very close to 43% found in a previous study (Susilo et al., 2014). Compared with leaves, roots stored more N (74.3 vs. 26.9 μg·d−1) during spike initiation but translocated more N to inflorescences during spike elongation and flower development (Table 5). These results are consistent with previous findings, where roots of phalaenopsis ‘V3’ stored more N than leaves during mature plant stage and partitioned more N to inflorescences during reproductive stage (Susilo et al., 2014).
The potential for tissue C and N composition to be a maturity index in phalaenopsis.
In juvenile stage, flowering cannot be induced even when the environment is appropriate for reproductive growth. As the plant grows and when forcing becomes possible, then a so-called mature stage is achieved. To ensure an accurate production plan, it is important for commercial growers to judge the maturity of phalaenopsis to determine the appropriate forcing schedule. In this research, although two phalaenopsis cultivars have huge difference in plant size, both cultivars had a decreasing trend in tissue N concentration (Fig. 2C and D). Data indicated that maturity was achieved at Stage M (10 months after deflasking) in the large, white-flowered ‘V3’ and Stage 6M (6 months after deflasking) in the small, purple-flowered ‘F2510’. In these stages, both cultivars had similar N concentration values near 2%. It is obvious that cultivars with short juvenile period had a faster rate of decrease in N concentration. In the small, purple-flowered ‘F2510’, N concentration decreased from 3.80% to 2.24%, during 6 months after deflasking (Fig. 2D). But in the large, white-flowered ‘V3’, N concentration only decreased from 4.63% to 3.83%, during 5 months after deflasking (Fig. 2C). This indicates that N concentration has the potential to become a maturity index. Future study is needed to construct a statistical prediction model.
In summary, C concentration in phalaenopsis had no obvious increasing or decreasing trend and neither did it have notable effects on C/N ratio in this research. N concentration in leaves decreased as leaves became more aged (from top leaf to bottom leaf). The middle part of the second mature leaf is an appropriate sampling position for tissue analysis in phalaenopsis. We compared C and N composition in two phalaenopsis cultivars, ‘V3’ and ‘F2510’, which had a huge difference in morphology. N concentration decreased as growth stage progressed from tissue-culture plantlet to mature plant in both cultivars, and C/N ratio consequently increased. N concentrations of plants at just-matured stages were around 2% in both cultivars, which indicates that N concentration is a potential maturity index in phalaenopsis. During reproductive growth stage, N concentration of small-flowered ‘F2510’ decreased, whereas that of large-flowered ‘V3’ had no significant change. This is attributed to the different size of N pool, where ‘F2510’ had smaller N pool size than ‘V3’. Major N sink shifted from roots to inflorescences during forcing and flowering in ‘F2510’. Newly absorbed N contributed 60% and stored N contributed 40% of total N to inflorescence development, indicating the importance of constant N supply during forcing. Results suggested that C and N are not evenly distributed in leaves and revealed the natural changes of C and N composition during various development stages. This research provides a better understanding of C and N partitioning in phalaenopsis, suggests a more precise sampling method, and offers information for a proper interpretation of tissue analysis results.
Literature Cited
Chen, W.S., Yang, L., Chen, W.H., Liu, H.Y. & Liu, Z.H. 1994 Gibberellin and temperature influence carbohydrate content and flowering in Phalaenopsis Physiol. Plant. 90 391 395
Chen, Y.J. 2014 Causes of lower leaf yellowing and symptoms of mineral nutrient deficiency in Phalaenopsis plantlets in vitro. Natl. Taiwan Univ., Taipei, Taiwan, MS Diss. (in Chinese with English abstract)
Hew, C. & Ng, C.K.Y. 1996 Changes in mineral and carbohydrate content in pseudobulbs of the C3 epiphytic orchid hybrid Oncidium Goldiana at different growth stages Lindleyana 11 125 134
Kataoka, K., Sumitomo, K., Fudano, T. & Kawase, K. 2004 Changes in sugar content of Phalaenopsis leaves before floral transition Sci. Hort. 102 121 132
Klebs, G. 1918 Über die blütenbildung von Sempervivum Flora oder Allgemeine Botanische Zeitung 111 128 151
Lee, N. & Lin, C.M. 1984 Effect of temperature on growth and flowering of Phalaenopsis white hybrid J. Chinese Soc. Hort. Sci. 30 223 231 (in Chinese with English abstract)
Lee, N. & Lin, C.M. 1987 Control the flowering of Phalaenopsis, p. 27–44. In: L.R. Chang (ed.). Proc. Symp. Forcing Cult. Hort. Crops. Special Publ. 10. Taichung District Agr. Improv. Sta., Changhua, Taiwan (in Chinese with English abstract)
Lee, N. & Wang, M.C. 1997 Changes in mineral composition and carbohydrate contents from juvenile to mature phase in white-flowered Phalaenopsis plants J. Chinese Soc. Hort. Sci 43 295 305 (in Chinese with English abstract)
Lei, H.Y. 2007 Changes of mineral composition and fertilizer requirement of Phalaenopsis during reproductive stages. Natl. Taiwan Univ., Taipei, Taiwan, MS Diss. (in Chinese with English abstract)
Malip, M. & Masri, M. 2006 Establishment of protocol for carbohydrate analysis and monitoring seasonal variations between carbohydrates and nitrogen levels in Garcinia mangostana (mangosteen) Acta Hort. 727 569 575
Mantovani, C., de Mello Prado, R. & Pivetta, K.F.L. 2015 Foliar diagnosis in Phalaenopsis orchid plants subjected to application of nitrogen Afr. J. Agr. Res. 10 4906 4912
Ng, C.K.Y. & Hew, C.S. 2000 Orchid pseudobulbs–‘false’ bulbs with a genuine importance in orchid growth and survival! Sci. Hort. 83 165 172
Poole, H. & Seeley, J. 1978 Nitrogen, potassium and magnesium nutrition of three orchid genera J. Amer. Soc. Hort. Sci. 103 485 488
Poole, H. & Sheehan, T. 1974 Chemical composition of plant parts of Phalaenopsis orchids Amer. Orchid Soc. Bull. 43 242 246
Royal Flora Holland 2017. Top 10 house plants sold. 1 Oct. 2017. <http://annualreport.royalfloraholland.com/?_ga=2.37418217.871361800.1493781265-328736619.1493781263#/feiten-en-cijfers/kamerplanten?_k=26z8df>
Sheehan, T. 1961 Effects of nutrition and potting media on growth and flowering of certain epiphytic orchids Amer. Orchid Soc. Bull. 30 289 292
Susilo, H. & Chang, Y.C.A. 2014 Nitrogen source for inflorescence development in Phalaenopsis: II. Effect of reduced fertilizer level on stored nitrogen use J. Amer. Soc. Hort. Sci. 139 76 82
Susilo, H., Peng, Y.C. & Chang, Y.C.A. 2014 Nitrogen source for inflorescence development in Phalaenopsis: I. Relative significance of stored and newly absorbed nitrogen J. Amer. Soc. Hort. Sci. 139 69 75
Susilo, H., Peng, Y.C., Lee, S.C., Chen, Y.C. & Chang, Y.C.A. 2013 The uptake and partitioning of nitrogen in Phalaenopsis Sogo Yukidian ‘V3’as shown by 15N as a tracer J. Amer. Soc. Hort. Sci. 138 229 237
Suto, K., Tsutsui, K. & Sinoda, K. 1984 Effects of temperature and nitrogen nutrition on the growth and flowering in nobile-type Dendrobium Bul. Veg. Ornamental Crops Res. Sta. 12 65 83
Tahir, F., Ibrahim, M. & Hamid, K. 2003 Seasonal variation in nutrient concentration of bearing and non-bearing terminals in mango (Mangifera indica L.) Asian J. Plant Sci. 2 113 115
Tanaka, T., Matsuno, T., Masuda, M. & Gomi, K. 1988 Effects of concentration of nutrient solution and potting media on growth and chemical composition of a Phalaenopsis hybrid J. Jpn. Soc. Hort. Sci. 57 78 84 (in Japanese with English abstract)
U.S. Department of Agriculture 2016. Floriculture crops 2015 summary. 3 Oct. 2017. <http://usda.mannlib.cornell.edu/usda/current/FlorCrop/FlorCrop-04-26-2016.pdf >
Wada, K. & Shinozaki, Y. 1985 Flowering response in relation to C and N contents of Pharbitis nil plants cultured in nitrogen-poor media Plant Cell Physiol. 26 525 535
Wang, Y.C. 2011 Effect of carbon and nitrogen on development and flowering of Oncidium Gower Ramsey. Natl. Taiwan Univ., Taipei, Taiwan, MS Diss. (in Chinese with English abstract)
Wang, Y.T. 1995 Phalaenopsis orchid light requirement during the induction of spiking HortScience 30 59 61
Wang, Y.T. 2003 Effects of N and P concentration on growth and flowering of the Phalaenopsis orchid HortScience 38 746 747
Wang, Y.T. & Gregg, L.L. 1994 Medium and fertilizer affect the performance of Phalaenopsis orchids during two flowering cycles HortScience 29 269 271
Wang, Y.T. & Konow, E.A. 2002 Fertilizer source and medium composition affect vegetative growth and mineral nutrition of a hybrid moth orchid J. Amer. Soc. Hort. Sci. 127 442 447
Xia, M.Z. 1993 The relationship between sugar-nitrogen ratio and reproductive organs abscission in faba bean (Vicia faba L.) J. Agron. Crop Sci. 170 348 353
Yoneda, K., Momose, H. & Kubota, S. 1991 Effects of daylength and temperature on flowering in juvenile and adult Phalaenopsis plants J. Jpn. Soc. Hort. Sci. 60 651 657 (in Japanese with English abstract)
Yoneda, K., Momose, H. & Kubota, S. 1992 Comparison of flowering behavior between mature and premature plants of Phalaenopsis under different temperature conditions Jpn. J. Trop. Agr. 36 207 210 (in Japanese with English abstract)
Yoneda, K., Usui, M. & Kubota, S. 1997 Effect of nutrient deficiency on growth and flowering of Phalaenopsis J. Jpn. Soc. Hort. Sci. 66 141 147 (in Japanese with English abstract)
Yong, J.W.H. & Hew, C.S. 1995 Partitioning of 14C assimilates between sources and sinks during different growth stages in the sympodial thin-leaved orchid Oncidium Goldiana Intl. J. Plant Sci. 156 188 196
Yu, Y.C. 2012 Growth response and gene expression profiling in Phalaenopsis under nitrogen, phosphorus, and potassium deficiency. Natl. Taiwan Univ., Taipei, Taiwan, MS Diss