The study emphasized on the effects

The study emphasized on the effects of brassin-like substance (BS) on fruit size of Arabica coffee (Coffea arabica L.). The experimental designed in randomized complete block design (RCBD) with 5 treatments and 4 replications, one tree per replication. The trees were sprayed with BS at the concentrations of 0, 0.1, 0.5, 1.0 and 1.5 mgL-1 every four weeks after fruit set until harvesting stage, 10 spraying times. The results showed that the coffee fruit applying with BS 1.5 mgL-1 treatment gave the largest fruit and bean sizes. It also gave the heaviest fruit and green beans. Application of BS at 0.5, 1.0 and 1.5 mgL-1 could hasten fruit ripening. However, application of BS at 1.0 and 1.5 mgL-1 decreased the percentage of fruit set and yield.

Keywords: Arabica coffee, brassin, brassin-like substance, coffee bean
Abbreviations: BS, brassin-like substance; BR, brassinosteroid; WAF, week after flowering


INTRODUCTION
Coffee is one of the most important cash crops in the world market. Thailand is the third largest coffee producer in Asia, after Vietnam and Indonesia. Arabica coffee is produced in the cooler highland areas of the northern part. It is worth up to $80 billion annually (Angkasith, 2002). It is exported as the raw, roasted, or soluble product to more than 165 countries worldwide. In year 2008-2009, the total area covered by coffee was about 4,000 hectares. Total production was 3,500 tons (Office of agricultural economics, 2009). Small fruit size is one of the limiting factors in coffee fruit marketing. Consumers also prefer large coffee bean (>5.5mm), making this a very important marketing consideration, and economic benefits from treatment capable of improving average fruit size are potentially very high. Only the beans that have the best grade, good flavor and aroma can be sold at a high price. In view of expected increases in production effective strategies for improving fruit size and quality are needed. Several techniques are used to improve coffee fruit and bean size, for example, girdling; fertilization; shading; irrigation; pruning, and fruit thinning (Vaast et al, 2005). However, the high labor cost for hand thinning does not suggest using this technique.
Brassinosteroids (BRs) are a new classified as group of plant hormones that are essential for normal plant development (Clouse and Sasse, 1998). Extensive research has revealed the importance of BRs involved in numerous processes, including cell elongation, cell division, vascular differentiation and reproductive development (Clouse, 2002). Many investigators evaluated and recommended this substance for increasing flowering, fruit and crop yield. Shalaby and Abdel-halim (1995) also reported that foliar spray of faba bean plants with brassinosteroids significantly increased number of pod, pod dry weight, number of seed per plant, and yield. Also Helmy et al. (1997) reported that foliar application of brassinosteroids significantly promoted the growth and yield characters of broad bean plants. Pankasemsuk, (2007) reported that application of brassin-like substance (BS) made by Department of Horticulture, Faculty of Agriculture, Chiang Mai University at the concentration between 0.01 to 0.50 mgL-1 on longan, papaya, and mango could increase fruit size and quality. The objectives of this study were to investigate the effect of BS on fruit size, maturation, quality, and yield of Arabica coffee.

MATERIALS AND METHODS
The experiments were conducted on five years old coffee, Coffea arabica L. ‘Catimor’. Trees of similar vigor, age and size were selected for spray treatments. Trees were grown at the Highland Coffee Research and Development Center, Chang Kian station: site A, Chiang Mai University, Chiang Mai, Thailand, at the altitude 1,200 m. above mean sea level. The experimental design was a randomized complete block design. The contour lines of the plantation were used as blocks. One tree per experimental unit and each treatment were replicated four times. BS was foliar sprayed on coffee plants at the concentrations of 0 (the control), 0.1, 0.5, 1.0 and 1.5 mgL−1 at 7 days after full bloom. Fruit were randomly collected every four weeks after full blossom until cherry fruit maturity (15 May to 15 February in 2011).
Fresh weight and dry weight of the whole fruit and bean: four bearing lateral branches per tree were randomly tagged. The sampled fruits were separated into bean, and oven dried at 70 °C for 48 hours to determine dry weight. The weight of whole fruit and bean were measured using a weighing balance. At the harvesting stage, coffee bean samples were prepared by the wet processing method (wet de-pulping, anaerobic fermentation for 24 hours, sun drying, de-husking) to obtain green beans. Fruit and bean width, length and thickness were measured using a digital vernier caliper.

RESULTS
Growth of the coffee fruit throughout the growing season was typical double-sigmoid curve pattern. It could be separated in to five stages:
1) The pinhead stage: the stage which spreads over the 1st to 5th weeks after flowering with phase of slow growth. There were no significant differences in fresh weight of fruit among all treatments
2) The rapid swelling stage: between 5th to 9th weeks after flowering; fresh weight of fruit increased rapidly. However, there were no significant differences among all treatments (Table 1).
3) The stage of suspended and slow growth (lag phase): between 10th to 16th weeks after flowering, but fresh weight of fruit was still low. In this stage, spraying coffee trees with BS 0.5, 1.0 and 1.5 mgL-1 could significantly increase fresh weight of fruit (Table 1).
4) The endosperm filling stage: from approximately the 17th to 25th weeks after flowering. For BS 1.0 and 1.5 mgL-1 treatments, the endosperm filling were greater than the control. The fresh weight of fruit was also heavier than the control (Table 1).
5) The ripe stage: from approximately 26th to 37th weeks after flowering. The fruit fresh weights were increased rapidly in this stage. For BS 0.5, 1.0 and 1.5 mgL-1 treatments, the rapid growths were determined one month before BS 0.1 and control. BS 0.5, 1.0 and 1.5 mgL-1 accelerated the fruit ripening approximately one month (Table 4).
At the harvest stage, the fresh and dry weights of fruit from 1.50 mgL-1 BS treatments were higher than other treatments (Table 2). Fresh and dry weight of bean presented significantly differences between treatments, which the heaviest bean weight was in 1.50 mgL-1 BS treatment (Table 2). Size of coffee fruit and coffee bean in term of width, length, thickness and volume from 1.5 mgL-1 BS treatment were higher than other treatment. Concentrate BS application (1.0 and 1.5 mgL-1) also significantly decreased the percentage of fruit set were 69.88 and 70.33%,respectively, compared to the control, BS 0.1 and 0.5 mgL-1 were 79.79, 80.24, and 80.54%, respectively. Fruit yields were decreased by BS treatment. Fruit yields in BS 0.5, 1.0 and 1.5 mgL-1 were 1,617.25, 1,605.75 and 1,554.75 g. per tree, respectively, were lower than the control and 0.1 mgL-1 BS treatments (2,392.5, and 2,195.5 g. per tree, respectively) (Table 4).