The flowering interval also was not

The flowering interval also was not influenced by the different GA3 concentrations, but it did vary in function of the leaf sequence of the plant (Figure 3). The fi rst, second, third and fourth leaves, produced from September 2010 to April 2011, presented a shorter average interval (50.181.63 days) (P≤0.05) in comparison with the fifth, sixth and seventh leaves, emitted from May to September 2011 (68.372.81) (Figure 3). The difference of 18 days for inflorescence emission in the two periods probably occurred due to the different prevailing climate conditions (Figure 1). It takes 60 to 80 days for good development of fl oral stems (DAÏ & PAULL, 1990), indicating that from a quantitative standpoint, the yield observed in the experimental period was adequate for commercialscale production. In Londrina, located in the north of the state of Paraná in southern Brazil, ASSIS et al. (2011) noted a reduction in the yield of inflorescences of the ‘Apalai’ in a shorter period of the year (May to July), attributed to the decreased temperature along with the lower light intensity and shorter days. In literature, the beneficial effects of gibberellin on anthurium were associated the floral initiation, increased number of inflorescences and its dimensions, however, this study the application of GA3 did not affect the dimensions of the inflorescences harvested, with the only variable having this effect being the time after the start of the treatments (Figure 4). The fl oral stem length, spathe width and length and spadix length, irrespective of the treatment, increased linearly with the leaf emission sequence (Figure 4). An increase in the size of inflorescences with increasing plant age was also observed in other studies (VAN HERK et al., 1998; DUFOUR & GUÉRIN 2003; ASSIS et al., 2011) indicating that this behavior is characteristic of the specie. The spathe, length and width and spadix length presented mean values, respectively, of 11.78, 14.40 and 8.45cm, in all cases greater than in other studies carried out with the same genotype (NOMURA et al., 2009; 2011). After the emission of the seventh leaf, the average inflorescence length reached 60 cm, the lowest value considered for flowerclassifi cation (LOGES et al., 2005). The appearance of the inflorescences also was not affected by the GA3. Of the 238 inflorescences harvested in the study period, 49 (20.49%) had defects that prevented their sale. However, only 4.08% of the inflorescences harvested between September 2010 and April 2011 had defects,against 95.91% of those harvested between May and September 2011, with spathe deformity being the most common fl aw. This is probably related to the different prevailing climate conditions in the period and the growth of the fl oral structure. Anthurium flowers produced in China when the average daily temperature was lower than 15C also presented this symptom of damage by cold (GAO et al., 2002).
The absence of a response in the number of inflorescences to the treatment with GA3 observed, in contrast to other studies, can be attributed to the frequency of application of the growth regulator and differences in plant management. In other producing countries, the cut flower is generally maintained with four leaves, and the young leaves are periodically removed from the plants to prevent competition with the inflorescence. Nevertheless, the response of anthurium to treatment with GA3 only in the vegetative part of the plant argues against recommending the application of this growth regulator by commercial flower growers.