Survey of varietal diversity and farmers' varietal preferences for intercropping systems

The on-farm survey was carried out from May to June 2017, to collect information about the diverse varieties used by farmers in intercropping systems, and to collect landrace seeds. Fifteen (15) villages spread around three municipalities (Boussouma, Korsimoro and Guibaré) (Fig. 1) were selected. These municipalities representative of the region have been identified as intercropping systems are of importance in farmers fields. Focus groups were organized in each of the 15 villages (one session per village). The main aim was to collect general information on the type of intercropping practiced in the region and the varieties grown. A first round of individual surveys was then carried out with 170 randomly-chosen farmers among those who had taken part in the focus groups (with each farmer representing a household). The number of farmers surveyed was 87 in seven villages in Boussouma, 47 in six villages in Korsimoro and 36 in two villages in Guibare. Farmers were chosen on a voluntary basis and because of their interest in intercropping systems. The targeted intercropping system involves placing the seed of both crops in the same seed hole, with different spatial arrangements (Ganeme et al., Reference Ganeme, Douzet, Traore, Dusserre, Kabore, Tirogo, Nabaloum, Ouédraogo and Adam2021). The data collected through a semi-structured questionnaire (Supplementary material/Questionnaire) focused on the types of cropping system, the varieties being grown and the respondent's preferred intercropping system. Finally a second round of individual surveys was carried out to collect farmers' perceptions about the morphological traits of the sorghum varieties suited to the most commonly practiced intercropping system.

After the survey, approximatively 200 g of seeds from farmers' landrace seed stocks were collected from the surveyed farmers in each village. The collected seeds were then used for our agro-morpho-physiological evaluation.

Agro-morpho-physiological evaluation of sorghum varieties

The agro-morpho-physiological evaluation was carried out on-station at the Saria experimental station of the Institute for Environment and Agricultural Research (INERA) (Fig. 1). The soils on this station are mainly tropical ferruginous soils such as Luvisols and Lixisols (Yelemou et al., Reference Yelemou, Yameogo, Bationo, Millogo-Rasolodimby and Hien2008). The evaluation was carried out during two rainy seasons (2017 and 2018). Total rainfall during the experiment was 794.45 mm (on 62 days spread over seven months) in the 2017 rainy season and 864 mm (on 68 days spread over eight months) in the 2018 season.

The plant materials used for the evaluation were 50 sorghum varieties comprised of 17 landraces collected from farmers during the surveys (2.1 section), eight improved varieties from the INERA breeding programme, six of which are already being grown by farmers (MRSI, 2014; Ganeme et al., Reference Ganeme, Douzet, Traore, Dusserre, Kabore, Tirogo, Nabaloum, Ouédraogo and Adam2021), and 25 newly-bred lines produced by participatory variety selection carried out on-farm within the framework of the INERA-Saria breeding programme (Sory et al., Reference Sory, Kondombo, Sawadogo, Vom Brocke, Kabore and Sawadogo2020; vom Brocke et al., Reference vom Brocke, Kondombo, Guillet, Kaboré, Sidibé, Temple and Trouche2020). The list of varieties is provided in the Supplementary Data (online Supplementary Table S1).

The experimental design was an alpha lattice with 10 blocks of five varieties per block in three replications. Plot size was two 6 m rows per variety. Sowing took place on 11 July in 2017 and 16 July in 2018, with an inter-row spacing of 80 cm and inter-hole spacing of 20 cm. Thinning was performed 15 days after sowing (DAS) to one plant per hole (1.6 plants m⁻²). Mineral NPK fertilization (14N-23P-14K-6S-1B) was applied at a rate of 100 kg ha⁻¹ at first weeding (14 DAS), and urea (46% nitrogen) at a rate of 50 kg ha⁻¹ at 45 DAS.

Ten quantitative agro-morphological traits were used to describe phenotypic diversity. The morphological data included plant height from the ground to the base of the flag leaf (heigfl, cm), length (lealen, cm) and width (leawid, cm) of the third leaf below the panicle, the total number of leaves (numtol), number of green leaves at maturity (numgrl) and stem diameter (stedia, cm). Assessments were made on four randomly chosen main stems per plot. These morphological traits were chosen because they are assumed to be important in terms of competition for light, and thus to make an essential contribution to performance in intercropping systems. Cycle length from sowing to 50% heading (cycle, days), dry straw yield at harvest (dry straw, kg ha⁻¹), grain yield (grain_yield, kg ha⁻¹) and 100-grain weight (seed_weight, g) were measured on a plot basis, as these are critical traits for assessing the overall performance of the plant and relating them to other traits. Finally, the classification of Harlan and de Wet (Reference Harlan and de Wet1972) was used to characterize the botanical races of the varieties evaluated.

Measurements of the photosynthetic activity of the 50 sorghum varieties were taken at the milk grain stage during the two rainy seasons (2017 and 2018). We did this because we assumed that the plant's ability to use available light efficiently can affect its performance in an intercropping system. These measurements were taken with a MultispeQ device, which is a phenotyping tool (Kuhlgert et al., Reference Kuhlgert, Austic, Zegarac, Osei-Bonsu, Hoh, Chilvers, Roth, Bi, TerAvest, Weebadde and Kramer2016) used to evaluate the environmental and phenotypic traits of plants, such as leaf pigmentation, and photosynthetic activity (plant growth capacity). Measurements were performed in each replication under optimum sunlight conditions between 9 and 11 a.m. on the third leaf below the panicle, on two randomly chosen plants per plot. The measured variables were (1) the percentage of incident light used for photosynthesis (Phi2, %) and, by extension, the amount of sugar produced (as needed for plant growth); (2) the percentage of incident light dissipated in the form of heat (PhiNPQ, %) to avoid damage to the photochemical system; (3) the percentage of unused incident light that could be harmful to photochemistry (PhiNO, %); (4) the light energy circulating in the chloroplasts after exposure to light (LEF), where LEF is an approximate measure of photosynthesis; and (5) the relative chlorophyll content of the leaf (%), an indicator of the plant's physiological status. These variables (Phi2, PhiNQ, PhiNO and LEF) are indicators of photosynthetic activity and provide an overview of plant status and the plant's capacity to resist environmental stresses (Baker and Rosenqvist, Reference Baker and Rosenqvist2004).

Ex situ characterization of the root systems

Root characteristics are a key element in soil resource capture, so it is essential to assess their range of variation. In 2017 and 2018, young plants of each of the 50 varieties were harvested during their vegetative stage, at 14 or 21 days, and their root systems characterized under controlled conditions using the Rhizoscope at CIRAD-Montpellier. The Rhizoscope (online Supplementary Fig. S1) is a tool for phenotyping the root systems of young plants (Borianne et al., Reference Borianne, Subsol, Fallavier, Dardou and Audebert2018). Trials were carried out in four containers of 48 rhizoboxes each and continuously supplied with a nutrient solution. Lighting, temperature and hygrometry were controlled throughout the experiment. Seeds were germinated beforehand and then placed at the top of the rhizobox (one seed per rhizobox), which was filled with small beads to support the roots (Audebert et al., Reference Audebert, Roques, Dardou, Rouan, Gozé, Frouin, Ahmadi, Oura, Ghneim and Courtois2012). Plants were allowed to grow for 14 days in 2017 and 21 days in 2018 before harvesting and taking measurements. The data collected per plant (using Fiji software) were as follows: root depth (root_depth, cm); root growth angle, i.e. the direction of root elongation with respect to the vertical (root_angle, °); number of roots (num20, num40); average diameter of the roots at depths of 20 and 40 cm (diam20 and diam40, cm); height of aboveground part (height); root dry matter (root_biom); aboveground dry matter (juv_biom).

Participatory assessment of the varieties

During the field evaluation, a participatory assessment of the 50 varieties was carried out at the maturity stage by 30 farmers in 2017 and 25 in 2018. The purpose of this assessment was to identify the varieties most liked by the farmers in the study panel so as to guide our final choice of varieties for future assessment in intercropping systems. The farmers were selected from among those surveyed on the basis of availability and willingness. The participatory assessment was based on the farmers' criteria for choosing their varieties (vom Brocke et al., Reference vom Brocke, Trouche, Weltzien, Barro-Kondombo, Gozé and Chantereau2010; Kondombo et al., Reference Kondombo, Deu, Chantereau, Martin, Chapuis, Letourmy, Zongo, Sagnard and vom Brocke2016). These criteria were cycle length (app_cycle), grain productivity (app_Prod), fodder (app_fod) productivity, plant height (app_hei), grain quality (app_gqu) and acceptability (app_acc). These traits were defined in agreement with farmers. Evaluation was done using a scale from 1 (bad) to 4 (excellent).

Two assessments were performed: group scoring and individual scoring. For the group scoring, each group was comprised of five farmers. Each group was encouraged to discuss among themselves before attributing a score on each of the six criteria for each variety (vom Brocke et al., Reference vom Brocke, Trouche, Weltzien, Barro-Kondombo, Gozé and Chantereau2010). In addition, each group was invited to indicate which variety they would like to keep, or use, in intercropping. For the individual scoring, each farmer assigned a score (ind_note) for each variety (taking all criteria into account), with a colour-coded card.

Data analysis

Descriptive statistics were used to describe the varietal diversity and main traits of interest for intercropping as reported by the farmers in the survey. The frequency of citation of a specific variety, its use as a sole crop or intercrop and the traits of interest for intercropping were calculated and plotted using R software (4.0.5 version). The traits mentioned by farmers were quantified (mean/average, minimum, maximum) using morphological data collected on-station on varieties obtained from farmers.

Analysis of the agro-morpho-physiological data first consisted of assessing the variability between the varieties for each quantitative trait by calculating the coefficient of variation (CV). Using the R package LmerTest (Kuznetsova et al., Reference Kuznetsova, Brockhoff and Christensen2017), linear mixed-effect models were fitted on all quantitative data collected, to estimate the variety effect. Variety was used as a fixed effect, whereas year, replication, block within replication and variety × year were considered random effects, following the mixed model described below:

$$Y_{ijkl} = \mu + G_i + \beta _j + \rho _{\,jk} + G_{i } \times \delta _l + \varepsilon _{ijkl}, \;$$

where μ is the general mean of the measured trait, G_i is the effect of variety, β_j is the effect of replication, ρ_jk is the effect of the block within replication j, G_i × δ _l is the variety × year interaction and ɛ_ijkl is the random error.

For the participatory assessment, the Kruskal–Wallis test was used to compare evaluation scores between varieties.

A principal component analysis (PCA) was conducted on quantitative agro-morpho-physiological traits with previously identified significant variety effects. This enabled us to identify the most discriminating variables. Hierarchical clustering for principal components was then performed, to identify different groups of varieties. Evaluation scores were used as quantitative supplementary variables in the PCA, to identify the group most appreciated by farmers according to their various traits. The FactoMineR package was used for the analysis, whereas the Factoextra and ggplot2 packages were used for the visualization and graphic representation of the data (Husson et al., Reference Husson, Josse, Le and Mazet2020). To test for significant differences, we described and compared these discriminating variables according to the groups of varieties obtained, using the multiple comparison method of the R Multcomp package (Bretz et al., Reference Bretz, Hothorn and Westfall2011).