Floriculture is not just about growing pretty plants: It is about growing profitable pretty plants. Increasing costs and flat prices have forced growers to more closely examine their production costs. When growers do this, three facts inevitably rise to the top:
These facts force growers to make important decisions to help streamline production. First, growers must reduce labor inputs by minimizing the number of touches a crop receives. Second, growers must look for crops that can be grown at cooler temperatures without adding too much time to production schedules. Third, growers must grow plants at higher densities than ever before. These three production decisions can be addressed simply by cultivar choices.
This past winter and spring, a study was conducted at Clemson University to survey osteospermum cultivars and identify a select group that could streamlined. By streamlined, we mean growing a series of cultivars that can be produced at high densities and will flower uniformly so the plants can be shipped in a bench-run fashion. To accomplish this, we grew all the cultivars in the Sideshow, Side, Cape Daisy and Crescendo series at a range of temperature treatments and then measured plant growth and flowering.
Current recommendations for osteos suggest that plants must be grown at 50º F or lower for 4-6 weeks to stimulate flower initiation, i.e., vernalization. However, our data suggest that modern osteo genetics have much more heat tolerance than in the past. For example, older genetics really did require relatively cold temperatures (50º F) to have significant flower initiation, while a new cultivar like ‘Sideshow Bicolor Purple’ flowers well even in a greenhouse maintained at 75º F day and 70º F night temperatures (72º F average daily temperature) (see Figure 1, right).
These results suggest the concept of vernalization no longer applies to all osteospermum. However, osteos still have a lower optimal temperature than many species. It should be noted that the longer an osteo is kept cool, the higher the flower count will be. For example, flower number per plant of ‘Nairobi’ decreased from 55 to 3 as the temperature increased from 48 to 72º F (see Figure 2, right). Thus, this cultivar does not produce an acceptable flower count (about 15 flowers) when grown at temperatures above 67º F.
The results shown in Figure 2, right, are derived from 12 different temperature treatment combinations. For example, we grew plants in 48, 60 and 72º F greenhouses and then moved plants among the different temperatures at two, four or six weeks after pinch. The results suggest the average temperatures from pinch to flower are more critical than the specific number of weeks at specific temperatures. This is very useful information for improving fuel efficiency, since it suggests that growers can maintain different temperatures depending on the ambient environments. In other words, the temperatures can be cooler on cold days and warmer on sunny days and the plants will still flower well. This flexibility saves money since growers do not need to cool or heat to hit a precise temperature requirement.
Every osteospermum grower remarks that plants stretch when finished warm and thus require more growth regulator. We used no growth regulators in our experiments and observed the tallest plants occurring at the coolest temperatures, while the shortest plants occurred at the warmest temperatures (see Figure 3, right).
This is quite an interesting contrast. Our current hypothesis is this: At warmer temperatures, the plants elongate more rapidly, however, they also develop much more quickly, thus they are elongating quickly but over a shorter period of time resulting in a shorter plant. At cooler temperatures, the plants elongate more slowly, but they elongate for many more days. The result is a tall plant.
Additionally, plant growth regulator treatments are likely to be more effective on plants grown cool compared to those grown warm. The bottom line is the increase in stem elongation rate is noticeable and plant growth regulation is important at warm temperatures; however, cool temperatures alone will not keep osteospermum short. Plant growth regulation is essential at all temperatures.
Predicting time to flower is critical for streamlining production, so we developed a table to help growers predict the remaining time for an existing flower bud to open at different average daily temperatures (see Figure 4, above). Visible buds are typically 3 mm in diameter (see Figure 5, below). Figure 4 indicates the number of days from any bud diameter until open flower at temperatures ranging from 48 to 72º F. For example, a 3-mm bud takes 55 days to open at 48º F but only 20 days at 72º F.
Notice that buds grown at warmer temperatures do not get as large prior to opening as those grown at cooler temperatures. Thus, a bud grown at 72º F will typically reach 10 mm in diameter prior to opening, while a bud grown at 48º F will grow to 12 mm prior to opening. Also, remember that not all cultivars will flower at a constant 72º F. Most Sideshow and Cape Daisy cultivars can be finished at 72º F provided the plants were grown at 48-60º F temperatures for four weeks after pinch. The Crescendo series does not have any cold requirement.
We have demonstrated that many osteos will tolerate warmer conditions than perhaps many growers would expect. However, these plants may still cease to flower at hotter July and August temperatures. To deal with this, we have divided the Ultra Osteo selections into early and late season selections. The early season cultivars can be started during winter, finished early spring and marketed as spring patio plants.
In the Southeast, these cultivars perform quite well for the consumer when purchased in early spring (March) and placed outdoors on a porch or patio where they will continue to flower for several months.
The late season selections include the most heat-tolerant cultivars, such as the Crescendo series. These can be sold throughout the spring garden season and continue to flower for several months for the consumer.
The Ultra Osteo concept will help growers interested in streamlining production and reducing fuel costs. Increasing crop uniformity will help reduce the number of touches applied to the crop, and the bud meter will help to more precisely hit target market dates. Our work on the temperature responses of osteos allows growers to have more flexibility in maintaining greenhouse temperatures. Ultra Osteo do not need a precise vernalization period, so growers can have more flexibility managing their greenhouse temperatures, which should allow for improved fuel efficiencies. The bottom line is that the program helps growers maintain profitability in these competitive times.