This study investigated the responses of Eremogone juncea flowering characteristics to exogenous 6-benzylaminopurine (BAP) and gibberellic acid3 (GA) treatments. Overwintered E. juncea plants were sprayed with seven treatments: no hormones; 200, 400, and 800 mg·L-1 BAP; and 200, 400, and 800 mg·L-1 GA. All treatments showed 100% flowering, and the exogenous BAP and GA treatments did not affect the time to flowering, whereas the hormone treatments influenced floral organ development. BAP significantly decreased the floret diameter and inflorescence length with increasing BAP concentration, although the 400 and 800 mg·L-1 BAP treatments showed similar values. BAP also caused abnormal flowers with a large gynoecium and stamens with small anthers and short filaments. However, GA significantly increased the floret diameter and inflorescence length, although 800 mg·L-1 GA treatment did not affect the floret diameter. In the vegetative parameters, the leaf length tended to increase as the GA concentration increased. These results indicate that BAP and GA affect the flowering quality of E. juncea and can enhance the value of cut flowers, such as flower size and inflorescence length, by making the flowers larger overall.

Minuartia laricina (L.) Mattf. is a Korean native plant with high potential as a commercial flowering potted plant due to its compactness and long flowering duration. However, because this plant is a groundcover, it is susceptible to lodging and leggy growth. Therefore, this study investigated the effects of plant growth retardants (PGRs) on the inhibition of stem elongation and flowering characteristics of M. laricina. Commercial products, Trimmit, Cycocel, and B-Nine, were used for the exogenous PGR application of paclobutrazol (PBZ), chlormequat chloride (CCC), and daminozide (DMZ), respectively. Application concentrations were 50 and 100 mg·L-1 for PBZ; 100, 500, and 1,000 mg･L-1 for CCC; and 500, 1,000, and 2,000 mg·L-1 for DMZ. Paclobutrazol was the only PGR that inhibited stem elongation. The stem lengths of the plants treated with 50 or 100 mg·L-1 PBZ were 2.2 cm (13%) or 9.8 cm (57%) shorter, respectively, than those of the control. 50 mg·L-1 PBZ retarded stem growth effectively without negatively affecting flowering or other growth parameters, whereas 100 mg·L-1 PBZ caused excessive dwarfing and significantly reduced flowering by 59%. CCC and DMZ applications were ineffective for growth control. Flowering time was accelerated with most PGRs, except for 2,000 mg·L-1 DMZ, reducing the time to flowering by 2–8 days. These results indicate that the stem growth of M. laricina was successfully inhibited with PBZ but not with CCC or DMZ. Thus, we concluded that a single application of 50 mg·L-1 PBZ or similar treatment is effective in miniaturizing M. laricina without causing harm to its growth or aesthetic value, such as the flower number. Additionally, because CCC and DMZ are not persistent in the growing medium, testing multiple application times for these PGRs is crucial.

본 연구는 paclobutrazol(PBZ) 처리에 따른 호접란의 생장 반응과 화경유도를 확인하기 위해 수행되었다. 20°C 생식생 장 환경에서 호접란 ‘Mantefon’과 ‘V3’ 실험묘를 0, 100, 200, 400ppm(유효성분 0, 1, 2, 4mg) PBZ 농도로 처리하였고, 28°C 영양생장 환경에서 ‘Mantefon’ 실험묘를 0, 100, 200ppm(유효성 분 0, 1, 2mg) PBZ 농도로 처리하였다. 화경유도 환경에서는 200, 400ppm 처리 식물들의 화경유도율이 감소하고 화경의 출 현이 늦어지는 것을 관찰하였다. 또한 ‘Mantefon’에서 처리 농도 에 상관없이 모든 PBZ 처리구에서 화경의 수가 감소하였다. PBZ 처리는 화경의 길이도 감소시켰으나 개화소요일수나 소화 의 수에는 차이가 없었다. 한편, 영양생장 환경에서는 처리 농도 가 증가할수록 줄기와 뿌리 직경, 잎의 두께는 증가하였고, 반면 에 신엽의 수, 잎의 길이와 폭은 감소하였다. 따라서 PBZ 처리를 받은 식물에서 ‘stunting’ 현상이 나타났다. 영양생장 환경에서 PBZ 처리를 받은 식물을 생식생장 환경으로 옮겼을 때도 앞선 실험에서와 마찬가지로 화경유도율이 감소하고 화경출현일수 가 증가하여서 영양생장 동안의 PBZ 처리 효과가 화경유도에까 지 이어질 수 있다는 것을 확인하였다. 이러한 결과를 통해 PBZ 처리는 호접란의 생장과 화경유도를 제한할 수 있다는 것을 알 수 있었다.

The effects of supplemental lighting (SL) timing on vegetative growth and the photosynthetic assimilation rate of young Cymbidium hybrids were examined. Nine month old C. ‘Yang Guifei’ and ‘Wine Shower’ were treated with four different SL timings: 22:00 – 02:00 (middle of the night, MN); 17:00 – 21:00 (end of day extension, DE); 07:00 – 09:00 plus 17:00 – 19:00 (both beginning and end of the night as split day extension, SDE), and non SL (8/16 h, short day, SD) for 4 months. All SL were provided by two types of 100% red LEDs (640 and 660 nm), with 150 μmol･m-2 ･s-1 and 800 μmol･mol-1 of CO2 supplied during the night (16 h). Pseudobulb diameters were significantly higher under SL treatments compared with the SD of both cultivars, irrespective of SL timing. Net photosynthetic assimilation rates were enhanced with increased SL, due to the additional photosynthesis and reduction of dark respiration. Thus, daily net photosynthetic amounts of SL treatments effectively increased photosynthesis compared to the SD. These results indicate that SL helps promote vegetative growth by enhancing photosynthesis. Since there were no significant differences among the SL timings when CO2 was provided uniformly during the night, we concluded that growth and photosynthesis of young Cymbidium do not depend on the timing of SL application, but are related to the daily light integrals, which is the amount of photosynthetically active photons delivered over 24 hours.

본 연구는 고농도 CO2 환경에 순응한 호접란 유묘의 CO2 교환 및 생장 반응을 조사하기 위해 실시하였다. 환경 조절이 가능한 식물생장상에서 6주령 호접란 ‘만천홍’을 27주 동안 야간에 각각 400 ± 100, 900 ± 100, 1500 ± 100, 2100 ± 100μmol CO2·mol-1 농도로 유지해주었다. 처리에 앞서 발달해 있었던 최상위 성숙엽으로 측정한 야간 중 CO2 흡수량은 900μmol CO2·mol-1 처리구에서 가장 높았고, 이어 2100, 1500, 400μmol CO2·mol-1 순으로 높았다. 그러나 처리 7주 이후 새로 발달한 성숙엽에서 측정한 결과, 2100μmol CO2·mol-1 처리구가 야간 중 가장 높은 CO2 흡수량을 보였으며, CO2의 흡수량은 처리 CO2 농도가 높아질수록 증가하는 경향을 보였다. 생장 반응에서는 최상위 성숙엽의 엽장, 엽폭 및 생체량은 900, 1500, 2100μmol CO2·mol-1 등 고농도 처리구에서 감소하였으나, 신엽 발달은 고농도 CO2 처리 하에서 촉진되었다. 이러한 결과들은 호접란 유묘의 높은 CO2 환경에 대한 적응이 CO2 흡수와 신엽 발달을 증진시킬 수 있다는 것을 보여준다. 그러나 900μmol CO2·mol-1 이상의 고농도에서는 잎의 생장과 생체량이 다소 줄어드는 경향이 있어 이에 대한 원인구명 등 추가적인 연구가 필요하다.

This study was performed to investigate how changing the period of light and dark influences the vegetative growth and the photosynthesis of Doritaenopsis Queen Beer ‘Mantefon’. Clones of Dtps. Queen Beer ‘Mantefon’ at 4-month-old stage were grown in a closed-plant factory system with four different light/dark cycles; 06/06 h, 08/08 h, 10/10 h, and 12/12 h. Temperature and relative humidity were set at 28oC and 80%, respectively, with a photosynthetic photon flux density of 160 ± 10 μmol·m-2·s-1. Repetitive measurements showed that the leaf length and the leaf width were the longest under 12/12 h closely followed by 10/10 h. The fresh weight and the dry weight of leaves and roots were the heaviest at 10/10 h treated samples. Different CO2 uptake patterns were observed from different light/dark cycles. Under 10/10 h and 12/12 h treatments, the CO2 uptake started at early dark period. When the light/dark cycles were shortened to 06/06 h and 08/08 h, the CO2 uptake started at the middle of dark period. Total CO2 uptake amounts were the highest under 12/12 h treatment followed by 10/10 h, 06/06 h, and 08/08 h treatments. Quantitative measurements showed that the vegetative growths under 10/10 h treatment were comparable with that of 12/12 h treatment. These studies indicated that manipulating light/dark can modify the photosynthesis patterns and vegetative growth of Dtps. Queen Beer ‘Mantefon’, resulting in the reduction of the production period.