A comparative study was carried out to determine the most suitable substrate for breeding of midges (Forcipomyia spp.) and the implications for pollination and yield in a typical cocoa production system in the forest ecological zone of Ghana. For the field experiment, the typically available substrates in cocoa farms which were used as the treatments under cocoa trees were : 1 ) rotten cocoa leaf litter ; 2 ) rotten cocoa pod husks ; and 3 ) rotten banana pseudostem. The un treated cocoa trees served as control. The experiment was set up in a randomized complete block design with three rep lications. For the laboratory experiment, the design was completely randomized design with four replications. The ob jective was to determine which substrate best supported breeding of the midges. The rotten banana pseudostem sub strate recorded the highest population (7680) of Forcipomyia spp. after 56 days of observation. The cocoa pod husk and cocoa leaf litter recorded populations of 5226 and 1920, respectively. Similar observations were recorded in the level of pollination of the cocoa trees treated with rotten banana pseudostem (95.78%), cocoa pod husks (89.05%) and cocoa leaf litter (68.42%). Application of all substrates to the cocoa tree resulted in a 77% mean reduction in flower abortion as compared to the control. Fruit abortion, on the other hand, was significantly greater in trees treated with rotten ba nana pseudostem (73.7%) and rotten cocoa pod husks (71.3%) than in trees treated with rotten cocoa leaf litter (54.3%). Application of banana substrate explained 88% of the variation in cherelle production (fruit set) whereas cocoa pod husks and cocoa leaf litter accounted for 71% and 94%, respectively, of the variation in cherelle production. The study concluded that although cocoa leaf litter resulted in average increases in midges population and subsequently not too high levels of pollination, there was a significantly higher number of set fruits retained which implied high cocoa pod yields. Consequently, in accordance with the observed trend cocoa leaf litter should be considered as the most appro priate substrate for midges activity in cocoa for high yields.
Ghana is the second highest producer of world cocoa with a tonnage of 1 million MT [
1) Evaluate the ecological importance of the various breeding substrates in the cocoa production system;
2) Determine the substrate preference for breeding by the midges (Forcipomyia spp.) and yield implications of the preferred substrate.
The study location called Kubease in the Ejisu-Juaben District of the Ashanti Region of Ghana lies between latitudes 6˚44'N and 6˚40'N and longitudes 1˚15'W and 1˚22'W (source: Gold Coast Survey Field Sheet No.129, Scale 1:62,500), and it is about 180 to 240 m above sea level. The natural forest belongs to the Trip-lochitonCeltis Association of the Tropical Moist Semi-Deciduous Formation [
The study was conducted over two years (2008 and 2009) during the peak of two flowering seasons (June and July) using six farmer-managed cocoa farms purposively selected based largely on accessibility and willingness on the part of the farmers. No chemical inputs such as fertilizers herbicides were used in these selected farms, a practice which is typical for the area. The experiment was a randomized complete block design (RCBD) with four treatments and three replicates. In each farm, ten adult flower-bearing cocoa trees between 20 - 25 years, within a 400 m2 plot were randomly selected and tagged. For eight consecutive weeks ( from June to July) 160 kg (20 kg/tree/week) of rotten cocoa leaf-litter collected from different parts of the farm were placed in a wooden quadrat measuring 1 m × 1 m around each of three randomly selected cocoa trees in each farm. Same mass of rotten banana pseudostem and rotten cocoa pod husks were collected and placed in wooden quadrats of same dimensions around each of three randomly selected cocoa trees. Three cocoa trees per farm were also left untreated to serve as the control. Thus, a total of 72 cocoa trees in six farm plots were used in the study. Fifty flowers per tree were labeled with a number tag that was attached by needle to the tree. Due to the fact that cocoa trees have a high flowering turnover new flowers were tagged every 3 to 4 days in order to maintain the total number of 3600 flowers. The relative importance of the substrates was evaluated using the following pre-maturity parameters of yield:
1) Flower set (an indication of successful pollination);
2) Fruit set before harvest (indicated by cherelle formation);
3) Fruit abortion, a premature loss of pollinated flowers (indicated by cherelle wilt).
The flower set was characterized by slight increase in purple coloration in the petals and sepals after 24 hours coupled with drying of the sepals which completed within 36 hours. Cherelle formation and aborted fruits (pod loss) were counted weekly for the eight weeks. The impact of the midges on cocoa pollination therefore, was determined by the number of targeted flowers that were pollinated as the substrates increased in quantities.
Although experimental and control plots were generally mixed together in the farms it was assumed that cocoa trees with greater densities of midges breeding beneath them have far greater fruit set because midges generally visit the flowers of nearby trees first, before moving to others [
A laboratory experiment was conducted to determine which substrate supported the highest population of the midges. The design was completely randomized with four replications. Rotten cocoa husks, rotten cocoa leaves, and rotten banana pseudostem were collected in polythene bags from different parts of the study farms and sent to the laboratory. Rotten cocoa leaves (50 g), rotten cocoa husks (50 g) and rotten banana pseudo stem pieces (50 g) were homogenized separately with 50 ml of water and the liquid extracts obtained by filtration through gauze.
Bioassay: Six emergence boxes measuring 20 cm × 20 cm × 20 cm each with 4 circular holes (d = 2 cm) on the lid, were filled with 3 kg of a common rotten substrate i.e. cocoa pod husk. The boxes were subjected to the following treatments: 2 g of cotton wool was wetted with 1 ml of the rotten cocoa leaves extract and packed tightly at the bottom of a test tube (l =150 cm; d = 24 cm). A second test tube was similarly treated and positioned directly opposite the first test tube. The third and fourth test tubes were also packed but with cotton wool wetted with distilled water to serve as controls. The four test tubes were placed upside down over the circular holes of the emergence box containing the substrate. An incandescent light was set about half a meter over and away from the box. Ten minutes after each flight observation, the test tube was removed while simultaneously covering the mouth of the test tube with cotton wool with chloroform, and the circular hole of the box with filter paper. Thus, only the midges found inside the test tube were recorded after each observation. For a total of 7 days in a month, the set-up was observed for 14 hours each day for three months. Hourly count (06.00 - 08.30) of the number of midge flights towards the extract or water in the test tubes was done. The whole set-up was repeated using extracts of rotten cocoa pod husks and subsequently the rotten banana pseudo stem pieces. The number of midge flights per hour was used as an indication of which substrate extract attracted most midges.
A follow up experiment was conducted to determine which substrate harbored the most adult midges. The design was completely randomized design with four replications. The six emergence boxes were divided equally among the three substrates. All the four test tubes per box were packed with cotton wool wetted with distilled water, and placed on the boxes as in the first study. An hourly count (06:00 - 18:00 h) of midge flights for 10 days per month for two months. Fresh substrates were used at the commencement of each 10-day observation, and were periodically moistened with distilled water to maintain the moist environment for the midges. The rate of flight per hour (i.e. average number of midges that emerged from the substrate per 15 minutes × 4) observed in the test tube was a proxy indication of population of midges in the substrates.
The field data were subjected to analysis of variance (ANOVA), using Statistix 8 software. Least significant differences (LSD) were calculated and the probability of treatment means being significantly different was set at P = 0.05. The number of flower sets, cherelles and aborted fruits were count data and therefore the data were square root transformed before analysis was done. Regression analyses were performed to determine relationships between substrates and flower sets, cherelles and aborted fruits.
For the laboratory study, two sets of analysis were carried out after the data was square-root transformed, to determine which of the substrates was most preferred for breeding. The first set of analysis was a series of t-tests to compare the attraction level of water and the substrate extracts. Since the base substrate cocoa pod husks, and the control, water were constant, the results would indicate which extract was preferable to the midges. The second set of analysis involved a one-way ANOVA of midges’ emergence from the six boxes. The population was indirectly determined by the rate of midge flight per hour (i.e. average number of midges that emerged from the substrate per 10 minutes × 6) from each substrate. All laboratory analysis was done using the SAS 9.0 (2005) version.
In both field and laboratory studies, midges’ populations were significantly (P < 0.05) greater under rotten banana pseudostem than the other substrates. Indeed, the population of midges’ was increased by 46.9% under the rotten banana pseudostem as compared to the cocoa pod husks and by 300% as compared to the cocoa leaf litter (
There were significant differences (P < 0.05) between the substrate types for flower set, flower abortion, fruit set and fruit abortion (
on the other hand, was significantly greater in trees treated with rotten banana pseudostem (73.7%) and rotten cocoa pod husks (71.3%) than in trees treated with rotten cocoa leaf litter (54.3%). The control (water treatment) lost 92.6% of fruit set through abortion (
Figures 1-6 present the relationships between the increasing weight of substrate types and the resulting fruit set and aborted fruits. Substrate application was a better predictor of the rate of cherelle production (Fruit set) (Figures 1, 3 and 5) than for fruit abortion (Figures 2, 4 and 6). Application of banana substrate explained 88% of the variation in cherelle production whereas cocoa pod husks and cocoa leaf litter accounted for 71% and 94%, respectively, of the variation in cherelle production. For fruit abortion however, substrate application was not a good predictor considering the lower R2 values, thus suggesting that other factors may also be involved in explaining the observed fruit abortion.
There was no significant inter-year difference in the
fruit or seed set of the pollinated flowers. There was however significant difference in the fruit proportions produced between the different treatments (t = 1.82; df = 238; p = 0.05), an indication that all the trees were not under the same pollinating conditions.
All the rotten substrates resulted in population increases in midges as compared to the water control. This supports [
Substrates which produced more flower sets had less flower abortion. Flower abortion has been attributed to low pollination or a reduction in auxin level due to delayed pollination [32,33]. Given the fact that the pollinator population determined the pollination intensity, the flower abortion could be higher under the control conditions where the lowest pollinator population was registered.
The positive linear relationships between the substrates and the production of cherelles was indicative that the presence of the substrates enhanced both the visitation rate and pollinator importance of the Forcipomyia spp. This therefore suggested that the deliberate accumulation of rotten plant material under cocoa trees must be encouraged to enhance pollination effectiveness and subsequent high fruit set. However, higher fruit abortion were recorded on cocoa trees with higher fruit set which, in the present study, were found on cocoa trees treated with rotten banana pseudostem and rotten cocoa pod husks. This phenomenon could be explained by the energy budget of the cocoa tree that determines its carrying capacity [34,35]. Since cocoa fruits contain up to 400 times more energy than flowers [
Each of the substrates found on the farms had significance in the cocoa ecosystem as they all harboured the cocoa pollinators. Additionally, all the substrates could play roles in the supply of nutrients to the cocoa crop. The tropical cocoa tree has up to several leaf production cycles (rhythmic, discontinuous flushes) per year [
The results of the study suggest that by increasing the habitat-carrying capacity, the population density of Forcipomyia spp. is enhanced. Earlier workers have observed that habitat destruction has been a problem in the pollination of cacao, and that the removal of rotting substrate in which the pollinating midges undergo larval development, have resulted in yield reduction [19,42]. Consequently [20,27] suggested placing banana and palm trunks, respectively, to encourage and maintain adequate pollinator forces. [43,44] indicated that the presence of plantain/banana as an intercrop of the cocoa production system influenced the abundance of ceratopogonids. The accumulation of substrates which leads to higher population density of the midges under natural farm conditions could be an indirect approach to breeding of pollinators in cocoa production systems.