Site selection

The experiment was established in Kapchorwa district in the eastern highlands (between 34.30° and 34.55° East and 1.18° and 1.50° North) and Kanungu district in the southwestern highlands of Uganda (between 29.69° and 29.86° East and −1.07° and −0.89° South), both located at an altitude of about 1800–1900 m above sea level. The districts have two rainy seasons per year, with an average annual rainfall of 1600 mm in Kapchorwa and 1200 mm in Kanungu. Soils in Kapchorwa are Nitisols and in Kanungu Acrisols and Andosols, with soil properties being relatively poorer in Kanungu than in Kapchorwa (lower pH, available P, K, Ca, and Mg) (Marinus, Reference Marinus2015).

The experiments were conducted in the first and second rainy season of 2016 (seasons 2016A and B, respectively) and took place on-farm in existing banana home gardens. Banana home gardens were selected if they were relatively well-managed in terms of application of household waste and/or manure (to presume uniform management conditions), if they contained only banana plants (no coffee or other crops), and if banana plants looked healthy (i.e., not affected by nematodes or other pests or diseases). Banana home gardens were selected if they contained early or mid-maturing varieties (most farmers grew a mixture of varieties on the same field) and if the plants were older than 1 year to ensure flowering during the experiment, which would allow for allometric measurements relating to banana bunch weights (Nyombi et al., Reference Nyombi, Van Asten, Leffelaar, Corbeels, Kaizzi and Giller2009; Wairegi et al., Reference Wairegi, van Asten, Tenywa and Bekunda2009). Densities of banana mats varied in the selected home gardens and this was accounted for by using mat density as a covariate in the analysis. The selected fields also had a piece of open land adjacent to it, which allowed for the establishment of two plots with sole crops of a local and improved climbing bean variety. No fields of sole-cropped banana were included, because it was assumed that banana yields were not affected by a climbing bean intercrop (Ntamwira et al., Reference Ntamwira, Pypers, van Asten, Vanlauwe, Ruhigwa, Lepoint, Dhed’a, Monde, Kamira and Blomme2014; Wortmann et al., Reference Wortmann, Sengooba and Kyamanywa1992), although the recent study of Ocimati et al. (Reference Ocimati, Ntamwira, Groot, Taulya, Tittonell, Dhed’a, Asten, Vanlauwe, Ruhigwa and Blomme2019) did find a significant decrease in bunch weight from the climbing bean intercrop after multiple seasons. In Kapchorwa, 13 trials were established in 2016A and 10 in 2016B, and in Kanungu 15 in 2016A and 14 in 2016B. Each farm hosted one unreplicated trial; hence, each farm represents one replicate.

Experimental design and management

Each experimental field within a farm covered an area of 12 × 12 m, consisting of four subplots of 6 × 6 m in a split-plot design with two levels of pruning and two climbing bean varieties, and two separate plots of 6 × 6 m with the sole-cropped bean varieties (Supplementary Material Appendix I). Pruning on the intercropped plots implied that all banana leaves were removed except the eight youngest leaves from the top. We tested this single pruning level which matches the moderate pruning levels practiced by farmers who intercrop their bananas. Retaining eight leaves was assumed not to affect banana yields, based on the earlier studies in DRC and experience in Uganda (G. Taulya, personal communication), but was still hypothesized to enhance light availability for beans. Pruning was done every 2 weeks, starting at planting of the beans. No pruning implied that all leaves were retained (varying from 9 to 11 green leaves). The local climbing bean varieties included in the experiment were NABE 10C in 2016A (released in 1999 and referred to as local varieties by farmers: “Atawa” in Kapchorwa and “Mubano” in Kanungu) and variety NABE 8C in 2016B (also released in 1999 and called “Kabweseri” in Kanungu). In both seasons, NABE 12C (released in 2005) was planted as the improved climbing bean variety. All bean varieties were type IV (indeterminate) varieties and were supported by one stake per two plants. NABE 10C takes 85–100 days to mature, NABE 8C 80–110 days, and NABE 12C 90–110 days (MAAIF, 2019).

Climbing beans were planted at a spacing of 50 cm between rows, and 25 cm between plants, which is recommended for climbing beans in sole cropping. For comparability, the same spacing was applied in the intercropped plots. In practice, farmers may plant intercrops at a wider spacing, but because legume intercrops have limited impact on banana yields, maintaining planting densities was assumed to maximize bean production if shading on the beans is reduced. Each plot then accommodated 11 rows of climbing bean, but the total number of bean plants per plot in intercropping varied with banana plant density. Each subplot contained about three to ten banana mats, depending on the farmer’s practice.

The experiment was implemented and monitored by field assistants. The field assistants took care of the pruning of bananas and instructed farmers when to weed their fields (twice per season). Farmers themselves managed the number of banana pseudostems per mat.

Light transmission measurements

Photosynthetically active radiation (PAR) was measured with use of the AccuPAR LP-80 (Decagon Devices Inc., Pullman, Washington, USA), shortly after planting beans and before staking, once per season in each of the subplots in 2016A and 2016B. Measurements of incident PAR were taken in a non-shaded area next to the banana field (the plants were too large to bring the sensor above the canopy). PAR levels were also measured below the banana canopy, but above the bean canopy, to capture what fraction of incident PAR was transmitted through the banana canopy and available for beans. The measurements were conducted before the beans were staked for ease of passage through the field, and no major differences in light penetration through the banana canopy were expected over the course of the season. The timing of measurements was between 10 am and 2 pm, and as much as possible under uniform conditions: either clear skies or uniform overcast skies.

PAR measurements in between the banana and bean canopy were taken along two perpendicular straight transects per subplot (Supplementary Material Appendix II). The transects were positioned along a row of banana plants, such that they passed banana plants at a distance of 0.5 m from the stem. Measurements were taken at intervals of 0.5 m along the transects, holding the AccuPAR probe perpendicular to the transect. Along with each measurement, field assistants recorded whether that position was fully, partly, or not covered by the banana canopy by looking upwards and judging whether they saw only banana canopy (fully covered), only the sky (not covered), or both (partly covered). At every measurement position, five PAR readings were taken rapidly after each other. The average was recorded for that position. Incident PAR measurements outside the canopy were taken every time a new (below-canopy) transect was started.

Climbing bean harvest

Before harvesting the whole subplot, climbing bean yields on intercropped subplots in Kanungu were assessed for two strips of approximately 1 × 2 m: the least and the most shaded parts of the subplot. The exact orientation and size of those strips were determined based on the positions of banana mats in each subplot, and they always covered (parts of) two rows of beans without any banana mats in it (Supplementary Material Appendix I). These strips served two purposes: 1) an additional assessment of the effect of light availability on climbing bean yield (difference in bean yield between the most and least shaded strip) and 2) a comparison with the sole-cropped climbing bean yield, as the strips did not have any banana plants in them and therefore had the same plant density as the sole-cropped subplots (difference in bean yield between shaded beans in intercropping and non-shaded beans as sole crops).

The yields of the two strips and of the remainder of the subplot together established the total climbing bean yield per subplot, for the assessment of bean yields per treatment and the assessment of differences between sole and intercropped beans including the reduction in plant population as a result of the banana intercrop. In Kapchorwa and on the sole-cropped bean subplots, only total yields of the whole subplot were assessed. All yields were reported as shelled, air-dried weights.

Banana measurements

The girth of the pseudostem base was recorded once for each banana plant per plot being in reproductive stage (flowering to harvest). Checks of banana plants entering the reproductive stage happened at regular intervals throughout the growing season. Banana pseudostem circumference shows an allometric relation with banana bunch weights (Nyombi et al., Reference Nyombi, Van Asten, Leffelaar, Corbeels, Kaizzi and Giller2009; Wairegi et al., Reference Wairegi, van Asten, Tenywa and Bekunda2009) and was used as an indication of any potential differences arising in banana production levels between the pruned and non-pruned plots. Pseudostem girth measurements starting from 2 months after the first pruning up to the end of the bean growing season were included.

The number of banana mats was recorded per plot. The distance between the banana mats in each plot, as well as the number of pseudostems per mat, was only recorded in 2016B. Field assistants also recorded the names of banana varieties grown in each plot and judged their leaf angles: erect, horizontal, or in between.

Field challenges

In season 2016A, only 5 out of 15 trials in Kanungu could be harvested – some climbing bean trials were planted late and failed to yield because of a dry spell in May, others were destroyed by hail, and 1 trial had no banana plants left as a result of Banana Xanthomonas Wilt. In Kapchorwa, 8 out of the 13 trials were harvested. The other trials were harvested by farmers themselves before recordings were taken. In the harvested trials, still some individual treatments failed to yield because of a dry spell towards the end of May, disease affecting the beans or animals damaging the field. Also in season 2016B, bean yields in Kapchorwa were completely destroyed as a result of a drought in the middle of the season. Therefore, only PAR measurements were taken and yield data and other agronomic measurements for 2016B were only available for Kanungu.

Statistical analysis

Linear mixed models were used to test differences in PAR transmission and crop yield between treatments. For PAR, a full set of data was available for Kapchorwa and Kanungu in 2016A and B. A model with farms as random factor and year and district as fixed factors was used to assess the overall effect of pruning on PAR transmitted:

(1) $${\rm{PAR}}\sim {\rm{year}}*{\rm{district}}*{\rm{pruning}} + (1|{\rm{farm}})$$

Agronomic data was missing for Kapchorwa 2016B (see “Field challenges”). A subset with combinations of PAR and agronomic data was therefore considered, in which the number of mats per plot (mean-centered) was included as a co-variable potentially influencing PAR. Year and district were combined in a single variable (year_district) to account for the imbalance in data:

(2) $${\rm{PAR}}\sim {\rm{year\_district}} + {\rm{mats\_per}}\_{\rm{plot}} + {\rm{pruning}} + (1|{\rm{farm}})$$

Climbing bean yields were assessed with the same subset of data. Bean yields were square-root transformed to ensure homoscedasticity of residuals. In case of interactions between year_district and treatments, the interaction was accounted for in the random part of the model, for instance:

(3) $${\rm{yield}}\sim {\rm{mats}}\_{\rm{per}}\_{\rm{plot}} + {\rm{variety}}*{\rm{pruning}} + ({\rm{variety}} + {\rm{pruning}}|{\rm{year\_district}}) + (1|{\rm{farm}})$$

To account for differences in the farmer-managed number of pseudostems per mat, a factor “pseudostems per plot” was derived from multiplying the number of mats per plot with the average number of pseudostems per mat in each plot. A model with this factor as co-variable (instead of the number of mats per plot) was tested for PAR and climbing bean yield in Kanungu 2016B.

(4) $${\rm{PAR}}\sim {\rm{pseudostems\_plot}} + {\rm{pruning}} + (1|{\rm{farm}})$$

(5) $${\rm{yield}}\sim {\rm{pseudostems}}\_{\rm{plot}} + {\rm{variety}}*{\rm{pruning}} + (1|{\rm{farm}})$$

Differences between the sole and intercropped bean yields were assessed with:

(6) $${\rm{yield}}\sim {\rm{sole}}\_{\rm{inter}}*{\rm{variety}}*{\rm{pruning}} + (1|{\rm{year}}\_{\rm{district}}) + (1|{\rm{farm}})$$

And the effect of PAR on climbing bean yields with:

(7) $${\rm{yield}}\sim {\rm{mats}}\_{\rm{per}}\_{\rm{plot}} + {\rm{PAR}}*{\rm{pruning}} + (1|{\rm{year}}\_{\rm{district}}) + (1|{\rm{farm}})$$

A Chi-square test was used to assess differences between the number of measurement points classified as fully, partly, or not covered among pruned and non-pruned plots. Software used was R Version 3.4.1 (2017).